NGSS Task Force: Health and Environment Report
Ensuring Safe and Reliable Underground Natural Gas Storage: Public Health and
Environment Subgroup Report Appendix to the Final Report of the Interagency
Task Force on Natural Gas Storage Safety
December 2016
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Executive Summary .................................................................................................................. 1
I. Introduction ...................................................................................................................... 9
II. Agency Responses to Address Gas Leak Health Concerns ........................................... 10
A. Summary of Actions Taken ........................................................................................ 10
B. Observations, Discussion and Recommendations ...................................................... 17
1. Unified Command ............................................................................................... 17
2. Expert Advisory Group ....................................................................................... 18
3. Regulator Coordination and Regulatory Authority Review ................................ 19
III. Ambient Air Pollutant Monitoring During the Incident and Public Health Risk
Assessment .................................................................................................................................... 20
A. Summary of Air Monitoring Actions and Health Risk Assessment ........................... 20
B. Observations, Discussion and Recommendations ...................................................... 36
1. Monitoring Network ............................................................................................ 36
2. Timeliness and Data Availability ........................................................................ 37
3. Pollutants of Concern .......................................................................................... 37
4. Background Concentrations of Pollutants ........................................................... 38
5. Health Effects ...................................................................................................... 39
6. Coordination and Expertise ................................................................................. 39
7. Detection Methods .............................................................................................. 39
8. Source Testing and Characterization ................................................................... 40
IV. Greenhouse Gas Emissions ............................................................................................ 41
A. Summary of Sampling and Results ............................................................................ 41
B. Observations, Discussion and Recommendations ...................................................... 47
1. Baseline Data....................................................................................................... 47
2. Release Uncertainty and Multiple Measurements ............................................... 47
3. Measurement Technology ................................................................................... 48
4. Inventory Tracking .............................................................................................. 49
V. Post Well Closure Indoor Air and Source Sampling/CASPER Health Assessment ...... 49
A. Summary ..................................................................................................................... 49
B. Observations, Discussion, and Recommendations ..................................................... 53
1. Contaminant Identification .................................................................................. 53
2. Source-Receptor Evaluation ................................................................................ 53
3. Post-Incident Sample Collection ......................................................................... 54
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4. Home Cleaning .................................................................................................... 55
5. Public Health Hazard Assessment....................................................................... 55
VI. Greenhouse Gas Mitigation Plan.................................................................................... 55
A. Summary ..................................................................................................................... 55
B. Observations, Discussion and Recommendations ...................................................... 57
1. Mitigating Releases of Short-lived Climate Forcers ........................................... 57
VII. Best Practices Summary ................................................................................................. 58
List of Acronyms .................................................................................................................... 61
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Federal Interagency Task Force on Natural Gas Storage Safety:
Public Health and Environment Subgroup Report
Executive Summary
On October 23, 2015, the largest methane leak from a natural gas storage facility in United
States history was discovered by the Southern California Gas Company (SoCalGas) at a well
within its Aliso Canyon Underground Storage Field in Los Angeles County. On November 19,
2015, the Los Angeles Department of Public Health (LADPH) issued a Public Health Directive
ordering SoCalGas to provide temporary relocation assistance to residents impacted by the
natural gas leak at its Standard Sesnon-25 well site (SS-25). After numerous attempts to stop the
leak, on February 11, 2016, SoCalGas reported that the leak had been temporarily sealed. On
February 18, 2016, California state regulators confirmed that the leaking well had been
permanently sealed. A full timeline of events can be found in Table ES-1.
Motivated by the events at Aliso Canyon, on April 1, 2016, the Obama Administration
formed an Interagency Task Force on Natural Gas Storage Safety to better understand the overall
safety and environmental impacts of our nation’s natural gas storage infrastructure. Congress
codified the Task Force through the Securing America's Future Energy: Protecting our
Infrastructure of Pipelines and Enhancing Safety Act of 2016 (PIPES Act). The Department of
Energy (DOE) and Department of Transportation (DOT) co-chaired the Task Force. Congress
directed the Task Force to review the Aliso Canyon events and make recommendations to reduce
the probability, and minimize the impacts, of any future occurrence of similar incidents at any of
the approximately 400 natural gas storage facilities across the country. The Task Force convened
three separate working groups to evaluate three aspects of the natural gas leak and response: (1)
the physical integrity of natural gas storage facilities, (2) the reliability of natural gas supplies,
and (3) the public health and environmental impacts associated with the leak. On October 18,
2016, the Task Force issued its final report, “Ensuring Safe and Reliable Underground Natural
Gas Storage,” which summarizes the findings and recommendations made by each of the three
working groups.1
This report addresses the public health and environmental impacts associated with the leak at
Aliso Canyon; the physical integrity of the storage facilities and the reliability of natural gas
supplies are addressed in separate reports. It was prepared by the Public Health and Environment
Subgroup established under the Task Force, whose members include the Environmental
Protection Agency, the Centers for Disease Control and Prevention, the Department of
Transportation/Pipeline Hazardous Materials Safety Administration, and the National Oceanic
and Atmospheric Administration. The scope of the report includes summarizing the actions taken
by local, state and federal agencies to monitor and mitigate impacts to public health and the
environment, reporting the best estimates of those impacts, and recommending actions for local,
state and federal agencies to take in order to be prepared in the event that a release from a natural
gas storage facility should occur in the future.
1 http://energy.gov/downloads/report-ensuring-safe-and-reliable-underground-natural-gas-storage
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State and local agencies began monitoring air quality near the leaking well and the nearby
Porter Ranch community within three days of discovery of the release. Within two weeks, state
and local agencies issued orders to SoCalGas to take actions to stop the leak, monitor the release,
and reduce impacts to the community. SoCalGas activated the Incident Command System (ICS),
as outlined in the National Incident Management System, to organize its response to the incident.
California and the Los Angeles metropolitan area have extensive experience with ICS principles.
As a result, the response was well-coordinated among federal, state and local authorities and
SoCalGas. However, earlier deployment of a Unified Command in the ICS structure, and the
presence of an expert advisory group, would have supported decision making and improved
public health messaging and community outreach.
Air quality monitoring carried out by the South Coast Air Quality Management District
(SCAQMD) and the California Air Resources Board (CARB), supplemented by monitoring
conducted by the Los Angeles Unified School District (LAUSD), SoCalGas, and the University
of California, Los Angeles (UCLA), provided the public and responding agencies with near-real-
time information about pollutants of concern.2 The report contains detailed information about
monitoring strategies and techniques, and summarizes state and local agency statements about
health risk based on collected air monitoring data. The report recommends that areas with natural
gas storage facilities have the capacity to establish similarly robust air quality monitoring in
order to adequately characterize the public health impacts of releases. Under a legal order issued
by the SCAQMD Hearing Board, research funded by SoCalGas will investigate whether there
could be long-term health effects from human exposures to pollutants emitted during the leak,
including natural gas odorants.
Methane, the primary component of the natural gas released during the leak, is a powerful
greenhouse gas. To assess the magnitude of the release, state and local agencies needed to
measure and quantify the amount of methane emissions released. Measurements were taken by
airplanes and satellites, near the ground around the well site, and at tall monitoring network
towers. The inventory of natural gas in the reservoir before and after the release was also
analyzed to estimate emissions. A number of studies estimated the magnitude of methane
released from the leak with varying results, as discussed in this report. CARB assessed data from
these studies and conducted its own analysis of additional data. On October 21, 2016, CARB
released an estimate of the leak of approximately 100,000 metric tons of methane. If a similar
leak were to occur elsewhere, it is unclear whether comparable quantification capabilities would
be available, because other natural gas storage facilities may not be covered by existing
monitoring networks and may not have access to multiple, rapidly deployable measurement
technologies.
After the leak was permanently sealed, many residents who had relocated from the Porter
Ranch community during the leak began to return home from temporary housing. From late
February to March 2016, LADPH received a large number of health complaints, similar to those
received during the gas leak, from the Porter Ranch community. These included symptoms such
as headaches, nasal congestion, sore throat, respiratory complaints, nausea and dizziness. In
2 We note that monitoring can serve different purposes. This report addresses monitoring that was conducted to
assess human exposure to chemicals emitted by the leak as well as the environmental impacts associated with
escaping GHG emissions. The report covering the physical integrity of natural gas storage facilities addresses
monitoring for the prevention, detection, and repair of leaks at natural gas storage facilities.
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response to these complaints, LADPH conducted an assessment of the indoor environment in
Porter Ranch homes as well as a Community Assessment for Public Health Emergency Response
(CASPER) health assessment. The results of these studies, which found elevated levels of
specific metals, led LADPH to direct SoCalGas to pay for professional home cleaning.
Subsequently, the Los Angeles County Superior Court ordered SoCalGas to clean nearly 1,500
homes of residents who were relocated. According to SoCalGas, all residents who were relocated
have returned home after the completion of exterior and interior home cleanings. LADPH had
the resources to undertake post well closure analyses to identify potential contaminants in the
homes and to conduct a community health assessment. Many of LADPH’s actions provide a
useful template for other agencies to consider if faced with similar situations.
Although not required by federal or state regulations, on December 18, 2015, SoCalGas
committed to “mitigate environmental impacts from the actual natural gas released from the
leak” and “work with state officials to develop a framework that will help us achieve this goal.”
On January 6, 2016, California Governor Jerry Brown ordered that CARB, “in consultation with
appropriate state agencies, shall develop a program to fully mitigate the leak’s emissions of
methane” and directed that, “the mitigation program shall be funded by the Southern California
Gas Company.” The lack of standards to guide voluntary mitigation of methane coupled with
ongoing litigation create uncertainty regarding the final outcome of mitigation. Furthermore, if a
similar leak were to occur elsewhere, there is no mechanism to ensure comparable mitigation
would take place.
The response to the Aliso Canyon natural gas leak was complex and without precedent.
Table ES-2 provides recommendations drawn from the Public Health and Environment
Subgroup’s analysis of actions taken by federal, state and local agencies to protect public health,
from the time the release was discovered until residents reoccupied their homes several months
after the leaking well was closed. The recommendations include a number of actions taken by
state and local agencies that could be considered “best practices.” State and local agencies, and
facility owners and operators, are encouraged to review these practices as they prepare for the
possibility of a similar incident in the future.
Table ES-1: Timeline of Events Associated with the Aliso Canyon Natural Gas Leak
Oct 23, 2015 Natural gas leak from well SS-25 was discovered by Southern California Gas (SoCalGas)
Oct 24, 2015 South Coast Air Quality Management District (SCAQMD) received the first air quality complaints resulting from odors associated with the natural gas leak.
Oct 26, 2015 SCAQMD began air sampling and monitoring activities in the local community.
Oct 30, 2015 SoCalGas began air sampling.
Oct 31, 2015 LA County Fire Department Health Hazardous Materials Divison (LA County Fire/HazMat) received a spill report from the California Office of Emergency Services (Cal/OES) and sent a team to investigate.
Late Oct – Dec 22, 2015
SoCalGas attempted seven separate “top kill” operations to seal well SS-25.
Nov 5, 2015 SCAQMD issued a “Notice to Comply” directing SoCalGas to abate the mercaptan odors from the natural gas leak.
Nov 7, 2015 California Energy Commission sponsored first airborne methane sampling collection. Flights continued through February, 2016.
Nov 10, 2015 SoCalGas provided a response to the “Notice to Comply” stating that its investigation and response to the leak incident was ongoing.
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Nov 10, 2015 National Aeronautics and Space Administration/Jet Propulsion Laboratory (NASA/JPL) conducted on-site field survey of the Aliso Canyon facility.
Nov 13, 2015 NASA/JPL began satellite imaging of methane plumes.
Nov 18, 2015 California Natural Resources Agency/Department of Conservation/Division of Oil, Gas and Geothermal Resources (DOGGR) issued order requesting SoCalGas to provide information on well SS-25.
Nov 19, 2015 Los Angeles Department of Public Health (LADPH) issued Public Health Directive ordering SoCalGas to continue abatement, eliminate odorous emissions, and provide relocation assistance.
Nov 23, 2015 SCAQMD issued Notice of Violation to SoCalGas for creating a public nuisance.
Nov 25, 2015 SoCalGas began drilling a relief well to conduct a “bottom kill” operation.
Nov 30, 2015 Los Angeles Unified School District (LAUSD) began air sampling.
Dec, 2015 SCAQMD and California Air Resources Board (CARB) deployed fixed site ambient air monitoring.
Dec, 2015 – Feb, 2016
California Public Utilities Commission (CPUC) issued a series of directives to SoCalGas for information related to the leak and operations at the Aliso Canyon field.
Dec 7, 2015 City of Los Angeles filed a civil lawsuit against SoCalGas seeking relief related to the leak’s climate impacts.
Dec 10, 2015 DOGGR issued order requiring SoCalGas to develop plans to capture escaping gas, stop the leak and communicate with state and local regulators.
Dec 16, 2015 EPA Federal On-Scene Coordinators (FOSCs) visited Aliso Canyon facility (with LA County Fire/HazMat).
Dec 18, 2015 EPA issued an information request to SoCalGas under Clean Air Act (CAA) Section 114 authority.
Dec 18, 2015 Governor Brown’s office issued a letter to SoCalGas and directed states agencies to investigate the well leak and public health concerns.
Dec 18, 2015 SoCalGas sent a letter to Governor Brown confirming company’s commitment to mitigate environmental impacts related to the leak.
Dec 21, 2015 SoCalGas contracted with Aerodyne to begin a tracer study to gauge methane concentrations downwind of the leak.
Dec 22, 2015 CARB installed first real-time community monitoring stations (sites 1 and 2).
Dec 24, 2015 CARB initiated a real-time data access portal on its website.
Jan, 2015 CARB and SCAQMD collaborated to expand the number of real-time community monitoring stations (sites 3-8).
Jan 3, 2016 SoCalGas began mitigation efforts to knock down mist escaping from well SS-25.
Jan 4, 2016 SoCalGas submitted a permit application to SCAQMD to construct and operate temporary equipment to capture and control natural gas from the leak.
Jan 6, 2016 Governor Brown’s office issued Emergency Proclamation to ensure thorough state response to the leak.
Jan 7, 2016 EPA activated its Regional Response Team 9 (RRT9) under National Oil and Hazardous Substances Pollution Contingency Plan authority (NCP, authorized by the Comprehensive Environmental Response, Compensation, and Liability Act (CERCLA)).
Jan 8, 2016 CalEPA’s Office of Environmental Health Hazard Assessment (OEHHA) issued first health risk assessment, based on a review of collected air sampling data.
Jan 13 – Jan 28, 2016
Dr. Michael Jerrett (University of California, Los Angeles, Fielding School of Public Health (UCLA FSPH)) collected air sampling data.
Jan 15, 2016 Public meeting was convened by State leadership, attended by EPA.
Jan 15, 2016 OEHHA convened panel of scientific and medical experts to review public health concerns.
Jan 22, 2016 SoCalGas entered into a Unified Command with the LA County Fire/HazMat and LADPH.
Jan 26, 2016 SCAQMD filed a civil penalty lawsuit against SoCalGas in LA Superior Court for creating a public nuisance.
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Feb, 2016 SoCalGas conducted a stored gas inventory analysis to estimate the methane emissions released by the leak.
Feb 2, 2016 LA County District Attorney filed a criminal lawsuit against SoCalGas.
Feb 11, 2016 SoCalGas reported that the leak had been temporarily sealed.
Feb 12, 2016 OEHHA’s expert panel issued report on public health risks related to the leak.
Feb 13, 2016 CARB released first preliminary estimate of total methane emissions based on recorded flight data.
Feb 16, 2016 CARB and SCAQMD issued “Criteria for Determining when Air Quality in the Porter Ranch and Surrounding Communities Has Returned to Typical (pre-SS-25 Leak) Levels.”
Feb 18, 2016 DOGGR issued a determination that the well leak was permanently sealed.
Feb 19, 2016 The Unified Command for the Aliso Canyon incident stood down; the CPUC began its lead role in the investigation phase of the incident.
Late Feb, 2016 Residents began returning to their homes from temporary housing.
Late Feb, 2016 LADPH began receiving a new influx of health complaints from the Porter Ranch community.
Late Feb, 2016 Dr. Michael Jerrett (UCLA FSPH) conducted indoor air and particulate sampling in seven impacted homes.
Mar 8, 2016 LADPH issued a Public Health Directive to SoCalGas to clean oily residue from surfaces in the Porter Ranch community.
Mar 10, 2016 LADPH began Community Assessment for Public Health Emergency Response (CASPER).
Mar 14, 2016 SoCalGas began indoor air sampling (results released March 17, 2016).
Mar 14, 2016 CARB released draft greenhouse gas (GHG) mitigation program recommendations for public comment.
Mar 23, 2016 LADPH announced a protocol for sampling home interiors for residual contamination from the leak (surface wipe sampling and indoor air sampling).
Mar 24, 2016 SoCalGas submitted comments on CARB draft GHG mitigation program.
Mar 31, 2016 CARB recommended a GHG mitigation program to address the leak’s climate impacts.
Apr 20, 2016 LADPH collected soil samples from six sites near the leak.
May 11, 2016 OEHHA issued latest health risk statement.
May 13, 2016 LADPH released a public health assessment report, “Environmental Conditions and Health Concerns in Proximity to Aliso Canyon Following Permanent Closure of Well SS-25.”
May 13, 2016 LADPH issued a directive to SoCalGas to offer comprehensive cleaning to homes in Porter Ranch.
May 20, 2016 Los Angeles Superior Court issued a ruling directing SoCalGas to pay for the cleaning of homes that participated in the relocation program.
May 25, 2016 LADPH directed SoCalGas to implement its Interior Home Cleaning Work Plan.
June 17, 2016 SoCalGas completed its indoor cleaning program,
Late June, 2016 SoCalGas ended the temporary relocation program.
Sep 13, 2016 SoCalGas agreed to pay $4 million to settle criminal charges filed by the Los Angeles County District Attorney.
Oct 18, 2016 Federal Interagency Task Force on Natural Gas Storage Safety issued its report, “Ensuring Safe and Reliable Underground Natural Gas Storage – Final Report.”
Oct 21, 2016 CARB released report, “Determination of Total Methane Emissions from the Aliso Canyon Natural Gas Leak Incident.”
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Table ES-2: Summary of Recommendations
Observation Recommendation
Section II: Agency Responses to Address Gas Leak Health Concerns
Unified Command A Unified Command should be formed early in response to a natural gas release, when human health and environmental threats are present and multiple jurisdictions are involved in the response effort. These jurisdictions could be represented by geographical boundaries, government levels (e.g., federal, state, local, tribal), functional responsibilities (e.g., fire, oil spill, emergency medical services), statutory responsibilities (e.g., Federal Land Managers, Responsible Party) or some combination thereof. The Unified Command should identify a liaison to the affected communities to ensure direct communication with affected residents.
Expert Advisory Group In jurisdictions with significant natural gas storage, facility operators, regulatory and other responding agencies should consider compiling and maintaining a roster of potential subject-matter expert advisors. The Unified Command could consult the roster to quickly convene a group to provide decision makers with advice on complex technical issues. Such an advisory group would be separate from the technical experts that are a normal component of the typical Incident Command System.
Regulator Coordination and Regulatory Authority Review
Regulatory agencies at federal, state, and, as appropriate, local levels should review their existing authorities and regulations related to natural gas storage facilities to identify potential gaps and to address them in a collaborative manner that builds upon the existing state certification program for intrastate gas pipelines.
Section III: Ambient Air Pollutant Monitoring and Public Health Risk Assessment
Monitoring Network
State and local monitoring agencies with natural gas storage facilities within their jurisdictions should have the ability to establish a robust ambient air monitoring network in the surrounding communities in order to adequately characterize the potential health impacts associated with natural gas leaks if resources are available. This includes access to real-time monitoring equipment for sulfur additive compounds, VOCs (hydrocarbons and aromatic compounds), SVOCs (e.g., naphthalene), methane, PM2.5, H2S, metals, and any other chemicals of concern identified by source data, as well as capability for instantaneous grab and 24-hour integrated samples.
Timeliness and Data Availability
State and local monitoring agencies should have an emergency air monitoring plan established to expeditiously deploy an ambient air monitoring network if a similar leak event were to occur. Having data early in the process would better enable agencies to reach timely decisions most consistent with public health protection (such as the decision to relocate residents). State and local monitoring agencies should also post their collected ambient air quality data in a prompt, easily accessible and easy-to-understand way.
Pollutants of Concern State and local monitoring agencies in jurisdictions with natural gas storage facilities should consider collaborating with natural gas storage facilities to develop facility-specific chemical fingerprints of the natural gas. If kill attempts are considered for sealing a leaking well, the kill fluid should also be analyzed for metals and other potential pollutants of concern. Once these chemical fingerprints are known, targeted monitoring plans should be developed in order to facilitate a quick and targeted response to a leak event. Such a plan should prioritize sampling pollutants of greatest health concern, which could include benzene, toluene, ethyl benzene and xylenes (BTEX), PM2.5 and hydrogen sulfide for air sampling.
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Observation Recommendation
Background Concentration of Pollutants
State and local monitoring agencies should consider collaborating with stakeholders to develop local background levels for methane and other pollutants of concern.
Health Effects Further research is needed to determine the acute and chronic effects of exposure to natural gas odorants (t-butyl mercaptan and tetrahydrothiophene). Relevant agencies should review the results of the SoCalGas-funded study ordered by the SCAQMD Hearing Board and consider any relevant findings or recommendations. Monitoring and analysis by state and local agencies should continue and risk data should be updated if conditions change.
Coordination and Expertise In the event of a future well leak, responding agencies should include health-related expertise in the response. Responding agencies should consider establishing a network of these health and risk assessment professionals prior to a leak event. After a leak has been identified, the network could be convened to meet regularly to assess collected air sampling data and the potential for health impacts from related pollutant exposures.
Detection Methods Natural gas facilities, and local and state agencies, should consider identifying laboratories with the capability of measuring sulfur compounds at lower detection limits. If feasible, analytical methods to detect odorants at concentrations below odor thresholds should be used and available during incidents.
Source Testing and Characterization
State and local air monitoring agencies should consider developing systems to safely collect source samples during a release and consider conducting robust source testing/characterization. Information collected on the chemical constituents of sources could be used in conjunction with air dispersion and deposition modeling to help inform decisions.
Section IV: Greenhouse Gas Emissions
Baseline Data State and local air monitoring agencies should consider having a methane monitoring framework. Baseline methane measurements would improve understanding of the magnitude of a leak. The framework and measurements should build on data that are already reported to federal/state/local agencies.
Release Uncertainty and Multiple Measurements
State and local air agencies should begin methane monitoring as soon as possible following initial leak detection. All monitoring should be coordinated with attempts to stop the leak in order to determine if those attempts decrease, increase or stop fugitive methane emissions. When possible, future leaks from natural gas storage facilities should be measured with multiple methods to confirm measurements. State and local air agencies should consider coordination with existing measurement and quantification efforts, such as those by universities and federal and state agencies active in methane and other air emissions monitoring efforts. These entities may have data or experience with monitoring in the area that could be of use.
Measurement Technology In advance of a leak, state emergency management agencies should determine whether they have access to aircraft and/or other mobile measurement technologies that can be rapidly deployed. Safety should be a consideration when flying in zones with high methane concentrations. Air agencies should also consider formalizing pilot projects involving state/local agencies, facility operators and federal agencies to deploy and evaluate some of the evolving methane measurement methods.
Inventory Tracking Studies of natural gas releases should quantify emissions in such a way that they can be included in inventories. An emissions estimate of the total mass of gas emitted by an event can be directly included in an inventory, while methane
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Observation Recommendation
concentration estimates at a given time cannot be included in an inventory without other information.
Section V: Post Well Closure Indoor Air and Source Sampling/CASPER Health Assessment
Contaminant Identification Given the evidence that materials used in well-kill fluids may be re-expelled and may contaminate the surrounding area, facility operators and emergency responders should use caution when determining the composition of the well-kill fluids and should consider the possible health risks that might result from exposure to toxic substances present in that fluid. Knowing the composition of the fluid would also facilitate environmental testing in the event of an accidental release. If a situation should occur where a large volume of kill fluid or other material is expelled along with natural gas, the appropriate state or local agency should test exposed homes for the presence of potential or known constituents before residents return. Soil samples taken at or near the source should be collected and analyzed for contaminants associated with the release, especially if residues resulting from a leak are found on or within structures at the facility or in a community and it is thought that these contaminants could pose a potential ingestion or inhalation risk. If enough information is known about the source and the expelled contaminants, dispersion modeling can be used to help make decisions regarding additional soil, surface water, and indoor sampling within the impacted community.
Source-Receptor Evaluation Collection and analysis of source and ambient samples should be conducted to enable evaluations of links between receptors (such as ambient monitors and residential surface samples), emissions from the leak, and emissions from other, nearby emission sources; and to support evaluations of health risks associated with exposure to the mix of emitted constituents. A more in-depth analysis of multiple relevant source trace element ratios, the ratios of samples from receptor sites, and use of sequential extraction would be appropriate in more complex leak situations.
Post-Incident Sample Collection
Responding agencies should plan for post-incident sample collection and analysis, and integrate this plan into the initial incident response to help mitigate post-incident exposures and to compress post-incident timelines.
Home Cleaning It is essential that in-home pollutant mitigation and cleaning activities only be performed by certified professionals under adequate supervision.
Public Health Hazard Assessment
State and local health and environmental agencies should consider developing standardized approaches for collecting health information and linking it with environmental monitoring data for use in public health hazard assessment if a similar leak event were to occur at other well sites.
Section VI: Greenhouse Gas Mitigation Plan
Mitigating Releases of Short-lived Climate Forcers
States with underground natural gas storage should review their legal authorities to require greenhouse gas mitigation of fugitive emissions from underground natural gas storage facilities. States interested in mitigation should review California’s approach as outlined in its Mitigation Plan.
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I. Introduction
On October 23, 2015, the largest methane leak from a natural gas storage facility in United
States history was discovered by the Southern California Gas Company (SoCalGas) at a well
within its Aliso Canyon Underground Storage Field in Los Angeles County. On November 19,
2015, the Los Angeles Department of Public Health (LADPH) issued a Public Health Directive
ordering SoCalGas to provide temporary relocation assistance to residents impacted by the
natural gas leak at its Standard Sesnon-25 well site (SS-25). After numerous attempts to stop the
leak, on February 11, 2016, SoCalGas reported that the leak had been temporarily sealed. On
February 18, 2016, California state regulators confirmed that the leaking well had been
permanently sealed.
Motivated by the events at Aliso Canyon, on April 1, 2016, the Obama Administration
formed an Interagency Task Force on Natural Gas Storage Safety to better understand the overall
safety and environmental impacts of our nation’s natural gas storage infrastructure. Congress
codified the Task Force through the Securing America's Future Energy: Protecting our
Infrastructure of Pipelines and Enhancing Safety Act of 2016 (PIPES Act). The Department of
Energy (DOE) and Department of Transportation (DOT) co-chaired the Task Force. Congress
directed the Task Force to review the Aliso Canyon events and make recommendations to reduce
the probability, and minimize the impacts, of any future occurrence of similar incidents at any of
the approximately 400 natural gas storage facilities across the country. The Task Force was
directed to assess three areas of concern arising from the Aliso Canyon incident: the physical
integrity of natural gas storage facilities, the reliability of natural gas supplies, and the public
health and environmental impacts of the release.3
The public health and environmental impacts were evaluated by a subgroup of the Task
Force, consisting of staff from the Environmental Protection Agency, the Centers for Disease
Control and Prevention, the Department of Transportation/Pipeline Hazardous Materials Safety
Administration, and the National Oceanic and Atmospheric Administration. During the course of
the evaluation, the Public Health and Environment Subgroup consulted with staff from state and
local agencies involved in responding to the leak, including the South Coast Air Quality
Management District (SCAQMD), the Los Angeles Department of Public Health (LADPH), the
Los Angeles County Fire Department/Hazardous Materials Division (LA County Fire/HazMat),
the California Air Resources Board (CARB), the California Natural Resources
Agency/Department of Conservation/Division of Oil, Gas and Geothermal Resources (DOGGR),
the California Office of Environmental Health Hazard Assessment (OEHHA) and the California
Public Utilities Commission (CPUC).
This report summarizes and analyzes the actions taken to understand and address impacts to
public health and the environment from the Aliso Canyon leak. Section II focuses on the actions
3 On October 18, 2016, the Task Force issued its final report, “Ensuring Safe and Reliable Underground Natural
Gas Storage,” which summarizes the findings and recommendations made by each of three working groups
convened by the Task Force. The report can be found at http://energy.gov/downloads/report-ensuring-safe-and-
reliable-underground-natural-gas-storage.
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taken by local, state and federal agencies to respond to the leak, including: (1) orders from state
and local agencies to SoCalGas to relocate residents of the nearby community, to stop the leak,
and to reduce its impact; (2) the federal government’s convening of an incident-specific National
Response Team (NRT) to coordinate the Federal agency response to the incident and EPA’s
activation of its Regional Response Team under the National Contingency Plan;4 and (3) the
formation of a Unified Command to direct the response and make decisions on how to stop, or
“kill,” the leak. In Section III, air quality monitoring, health risk assessments, and consideration
of health symptoms reported by the public are discussed, spanning the time period from the
leak’s discovery through the closure of the well in February, 2016. Section IV summarizes the
multiple efforts to quantify the release of greenhouse gas emissions from the leak. Section V
describes the responses to public health complaints from residents as they began returning home,
how the home environments were tested to assess exposures to pollutants of concern, and efforts
to determine whether the reported symptoms were the result of the leak. Section VI summarizes
actions taken to mitigate the climate effects associated with the greenhouse gases leaked into the
atmosphere.
In each section, the summary of actions is followed by an analysis, structured as observations
drawn from the response, discussions and recommendations. The recommendations are designed
to inform facility operators and federal, state and local agencies with natural gas storage facilities
within their jurisdictions of actions they may take to be prepared for the public health and
environmental impacts of an incident similar to the Aliso Canyon release. A list of the
recommendations may be found in Table ES-2.
II. Agency Responses to Address Gas Leak Health Concerns
A. Summary of Actions Taken
Background
On October 23, 2015, an uncontrolled release of natural gas was discovered by the
SoCalGas at the Aliso Canyon Natural Gas Storage Facility (Aliso Canyon facility), in the
northern San Fernando Valley, Los Angeles County, California. SoCalGas uses an abandoned oil
reservoir at the Aliso Canyon facility as storage for natural gas. Natural gas is injected into the
old sandstone reservoir formation at approximately 8,200 feet below ground surface for storage,
and withdrawn for transmission and sale in response to market conditions. SoCalGas, a
subsidiary of Sempra Utilities, is the owner and operator of the Aliso Canyon facility.
The Aliso Canyon facility contains 115 gas withdrawal/injection wells. The well that was
the source of the leak, SS-25, was converted for use as a gas storage well in June 1973. The
4 The National Oil and Hazardous Substances Pollution Contingency Plan (NCP) provides the organizational
structure and procedures for preparing for and responding to discharges of oil and releases of hazardous substances,
pollutants and contaminants. 40 Code of Federal Regulations Part 300.
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Aliso Canyon facility has a total working storage capacity of 86 billion cubic feet (bcf) of natural
gas,5 making it one of the largest natural gas storage facilities in the United States. The leak
initially released approximately 53 metric tons of methane per hour, resulting in a total of
approximately 1,300 metric tons of methane released every day. A monthly greenhouse gas
output of this size is approximately equivalent to the annual greenhouse gas emissions from
200,000 cars. Multiple actions were taken to address the leak and associated health concerns
before the leak was fully controlled on February 18, 2016.
Porter Ranch, a residential community of approximately 30,000 people, is located near
the Aliso Canyon facility. The Porter Ranch properties nearest to SS-25 are located
approximately one mile away and 1,200 feet below the leaking wellhead. Immediately after
discovery of the leak, many residents began reporting odor complaints (related to mercaptans,
the familiar sulfur-smelling odorant added to natural gas for safety) to various local and state
agencies, including 911. The LA to the complaint and sent personnel to the scene. The
responding personnel were informed of non-emergency circumstances of the incident at the gate
of the facility by SoCalGas and departed. SoCalGas telephoned the LA on October 24, 2015, and
reported that the incident should be resolved by 6:00 PM PST.
Many Porter Ranch community members experienced adverse health impacts in the days
following the leak. On November 19, 2015, the LADPH determined that emissions from SS-25
had caused health symptoms in some Porter Ranch residents and ordered SoCalGas to provide
temporary relocation to residents who desired to move.6 In its directive to SoCalGas, LADPH
noted that inhalation of methane in the outdoor environment was not thought to pose a direct
health threat to community members, but indicated that the added mercaptans did pose a health
threat to the community, by way of possible short term neurological, gastrointestinal and
respiratory effects upon inhalation.
Initial Monitoring and Regulatory Actions
The South Coast Air Quality Management District (SCAQMD), one of the largest and most
technologically sophisticated air pollution control agencies in the world, covers Orange County
and the urban portions of Los Angeles, Riverside and San Bernardino Counties. SCAQMD
started receiving odor complaints from Porter Ranch residents on October 24, 2015, and began
ambient air quality monitoring soon thereafter. SoCalGas began its own air sampling effort on
October 30, 2015. This monitoring, in addition to ambient air quality monitoring conducted by
the CARB and other entities, is described in detail in Section III. On November 5, 2015,
SCAQMD issued a “Notice to Comply” that required SoCalGas to take specific steps to abate
the natural gas leak, monitor the leaking gas, and reduce the impacts of nuisance odors on the
local community.7 On November 10, 2015, SoCalGas provided a written response to the Notice
5 The natural gas stored at Aliso Canyon is approximately 95% methane with the remaining portion consisting
of non-methane hydrocarbons such as ethane. See Methane emissions from the 2015 Aliso Canyon blowout in Los
Angeles, CA; Science, 18 March 2016, p. 1318 6 http://publichealth.lacounty.gov/eh/docs/AlisoCanyon.pdf 7 South Coast Air Quality Management District Notice to Comply E-26893, http://www.aqmd.gov/docs/default-
source/compliance/aliso-cyn/so-cal-gas-aliso-canyon---notice-to-comply-e26893.pdf?sfvrsn=2
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indicating its investigation of the events surrounding the incident and the ongoing response
efforts.8
On November 7, 2015, the California Energy Commission (CEC) sponsored the first airborne
methane sampling effort. Flights continued through February, 2016. On November 10, the
National Aeronautics and Space Administration/Jet Propulsion Laboratory (NASA/JPL)
conducted an onsite field survey of the Aliso Canyon facility, and began satellite imaging of
methane plumes on November 13, 2015. Monitoring for methane is described in more detail in
Section IV.
DOGGR and the CPUC had the most direct operational oversight at the Aliso Canyon
facility. Pursuant to the federal Pipeline Safety Act, DOGGR had this oversight role because of
its delegated authority from the Department of Transportation/Pipeline Hazardous Materials
Safety Administration (DOT/PHMSA) to conduct regulatory oversight of underground natural
gas storage facilities in California. In early November, DOGGR convened a panel of technical
experts from the Lawrence Berkeley National Laboratory, Lawrence Livermore National
Laboratory and the Sandia National Laboratory to provide independent expertise to assist the
Division in monitoring and evaluating SoCalGas actions.
DOGGR issued two orders to SoCalGas, one on November 18, 2015 and a second one on
December 10, 2015.9 The November 18 order required SoCalGas to provide information on SS-
25; the December 10 order required SoCalGas to develop plans to expeditiously capture the
escaping gas, stop the leak and communicate with state and local regulators. The December 10
order also required SoCal Gas to provide access to the SS-25 site and information to a group of
experts from the DOE National Laboratories (Lawrence Berkeley, Lawrence Livermore and
Sandia) who were assisting DOGGR in evaluating SoCalGas’ plans for stopping the leak. The
CPUC also provided directives to SoCalGas regarding its response to the incident via a series of
letters issued between December 2015 and February 2016. These letters requested a variety of
information including: (1) data on gas withdrawal rates from the Aliso Canyon field; (2) how gas
withdrawal was affecting the leak at SS-25; (3) the cost to SoCalGas of addressing the leak at
SS-25; (4) the volume and cost of the leaked methane; (5) information on the surface gas capture
system design; (6) the retention of records and preservation of evidence by SoCalGas and (7)
assistance by SoCalGas to CPUC’s third party that conducted a root cause analysis of the SS-25
failure.10 The information collected by CPUC from SoCalGas informed the steps that were taken
by state regulatory agencies to address the gas leak, investigate its root causes and model how an
interruption in the operation of the Aliso Canyon facility might impact the availability and
reliability of power generation in the Los Angeles Basin in 2016 and 2017.
8 See http://www.aqmd.gov/docs/default-source/compliance/aliso-cyn/1-19-16-clean-socal-gas---alison-
canyon---proposed-findings-and-decision.pdf?sfvrsn=4, page 4, lines 1-3 9 Emergency Order No. 1104; November 18, 2015, Provide Data Re: Aliso Canyon Storage Facility;
Emergency Order No. 1106; December 10, 2015, Provide Data and Take Specified Actions Re: Aliso Canyon
Storage Facility 10 Letters from CPUC to SoCalGas, dated December 11, 2015, December 14, 2015, December 23, 2015,
January 4, 2016; January 14, 2016; January 18, 2016; January 20, 2016, January 22, 2016 and February 2, 2016
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The Los Angeles County Fire Department had an active operational presence with SoCalGas
starting in November. They deployed a ‘short Incident Management Team’ to work with the
SoCalGas Operation and Planning Sections, preparing Incident Action Plans and other
documents, and reviewing operations. The California Office of Emergency Services (Cal/OES)
was also present from the first weeks of the incident.
Initial Federal Actions
On December 4, 2015, PHMSA’s Office of Pipeline Safety began to provide technical
assistance to the CPUC on the leaking Well SS-25 at Aliso Canyon. On December 20, 2015,
PHMSA began to participate in daily Incident Command calls led by SoCalGas. DOT/PHMSA
conducted a site visit at Aliso Canyon on December 22, 2015.
The United States Environmental Protection Agency (EPA) became actively involved in the
Aliso Canyon incident in early December at the request of the California Office of Emergency
Services and entered into an informal, federal multi-agency coordinating group with
DOT/PHMSA and DOE. On December 16, 2015, two EPA Federal On-Scene Coordinators
(FOSCs) conducted a site visit at the Aliso Canyon facility with LA County Fire/HazMat. The
EPA FOSCs' assessment concluded that SoCalGas appeared to have well-control experts with
the appropriate knowledge in charge of the site operations. From early December 2015 to the
cessation of on-site activities in February 2016, the EPA participated in multiple daily calls,
briefings and updates with federal, state and local partners. Federal agencies included DOE,
DOT/PHMSA, Department of Interior/Bureau of Safety and Environmental Enforcement
(DOI/BSEE), and Department of Commerce/National Oceanic and Atmospheric Administration
(DOC/NOAA).
In early December the FAA issued a Notice to Airmen (NOTAM) restricting pilots from
flying aircraft within a half-mile radius of the Aliso Canyon storage facility. The restriction
extended up to 2,000 feet above the surface. The flight restriction expired on March 8, 2016.
Operations to Plug SS-25
Starting in on October 24, 2015 and continuing until December 22nd, SoCalGas conducted
seven separate “top kill” operations to stop the leak. 11 SoCalGas also began planning for the
drilling of a relief well for a “bottom kill” operation, if needed. “Top kill” operations involve
pumping heavy drilling muds, fluids and other material (together known as “kill fluids”) into the
leaking well in an attempt to plug the well from above. “Bottom kill” operations involve drilling
a relief well to intercept the leaking well at depth and pumping drilling muds and cement through
the relief well into the leaking well to seal the well.12 None of the top kill operations were
successful. After the failed first well kill attempt on October 24, SoCalGas retained the services
of Boots & Coots, a wholly owned subsidiary of Halliburton, for assistance on October 25, 2015.
Boots and Coots is a recognized expert in well control services.
11 The seven top kill attempts occurred from late October to late December 2015 on the following days:
October 24th; November 13th, 14th, 18th, 24th, and 25; and December 22. 12 The fluids used contained calcium chloride polymers, barium sulfates, monocarboxylic acids and light
petroleum distillates, all common constituents of drilling muds; the top kill attempt on November 13 introduced inert
materials such as walnut shells into SS-25, along with weighted muds.
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On November 25, 2015, SoCalGas began drilling a relief well in order to conduct a bottom
kill operation. In early December 2015, SoCalGas began withdrawing natural gas from the Aliso
Canyon facility at a rate of approximately one billion cubic feet per day (bcf/day), in an effort to
reduce pressure around SS-25. SoCalGas also started preparing for a second relief well, should it
become necessary. The first relief well was ultimately successful in plugging SS-25 and no other
relief wells were drilled.
In at least one top kill attempt, significant volumes of kill fluids were expelled from the
borehole by the escaping gas. Because the Aliso Canyon storage facility uses abandoned
petroleum-bearing formations, the escaping gas also caused residual petroleum from these
formations to become aerosolized and expelled from the well bore, resulting in the deposition of
an oily residue on the outside of many Porter Ranch residences, vehicles and outside areas. It is
believed that these unsuccessful top kill attempts partially aerosolized some kill fluid
constituents, such as barium, and that these aerosolized products, in the form of an oily mist,
were in turn carried in the air and deposited in the interior of some Porter Ranch residences. To
mitigate this problem, starting on January 3, 2016, SoCalGas installed a series of metal screens,
called coalescing trays, over SS-25 to contain this oily mist. See Section V for a discussion of the
efforts to assess the presence of aerosolized pollutants within homes in the affected area, as well
as efforts to clean the homes that were exposed to the oily mist.
In response to the December 10, 2015 order from DOGGR to develop plans for capturing
the methane at the surface, SoCalGas submitted a permit application to the SCAQMD on
January 4, 2016, to obtain approval for construction and operation of temporary equipment to
capture and control natural gas from the leaking well. SoCalGas ultimately abandoned this effort,
after several weeks of investigation and design work, due to significant safety concerns raised by
LA County Fire and the company’s well-control experts regarding the feasibility of constructing,
installing and operating a gas capture system in a methane-rich environment.
On January 6, 2016, California Governor Jerry Brown issued a proclamation declaring a
State of Emergency in Los Angeles County as a result of the natural gas leak at the Aliso Canyon
facility. The Governor’s emergency proclamation provided for “all state agencies to use
personnel, equipment and facilities to ensure a thorough and continuous response to the incident,
as directed by the Governor's Office of Emergency Services and the State Emergency Plan.”13
The emergency proclamation contained requirements for a number of state agencies, including
the CPUC, the CEC, the CARB, OEHHA, the California Independent System Operator (CA
ISO) and DOGGR regarding stopping the leak, protecting public safety, ensuring accountability
and strengthening oversight of gas storage facilities.
Further Federal Action
On January 4, 2016, PHMSA and the EPA met to discuss the convening of a National
Response Team (NRT) to coordinate the Federal agency response to the incident. The NRT is a
13 Proclamation of a State of Emergency, January 6, 2016, by Governor Edmund G. Brown for the County of
Los Angeles due to the natural gas leak
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component of the National Response System (NRS) that consists of fifteen federal agencies
specified in Section 300.175(b) of the National Oil and Hazardous Substances Pollution
Contingency Plan (NCP) and is responsible for carrying out national response and preparedness
planning, coordinating regional planning, and providing policy guidance and support to incident-
specific Regional Response Teams (RRTs).14,15 On January 7, 2016, the EPA activated its
Regional Response Team 9 (RRT9). That same day, the EPA reported progress and updates to
the DOT/PHMSA, DOE, the Federal Emergency Management Agency (FEMA) and (Cal/OES).
On January 8, 2016, PHMSA and the EPA reported progress pertaining to the Aliso Canyon
response to the White House National Security Council (NSC) Domestic Resilience Group
(DRG). The EPA agreed to report back on the progress by state and local agencies to assess the
short- and longer-term public health impacts of the release. SoCalGas Executives also briefed
DOT at their headquarters. The full NRT convened on January 11, 2016, to discuss the Aliso
Canyon incident.
On January 11, 2016, RRT9 briefed the NRT on the Aliso Canyon incident. RRT9
requested that the NRT convene a federal interagency panel of well-control experts to advise and
consult on the safety and operation of the gas capture and disposition system being proposed by
SoCalGas, which would have captured the leaking natural gas at the surface of SS-25. The gas
capture system was essentially a giant, inverted funnel and flare system that would capture the
gas escaping at the surface, direct it away from the well head through pipes and incinerate it. As
noted above, this proposal to capture and incinerate the leaking gas was ultimately abandoned
due to significant safety concerns.
PHMSA leadership met with the CEOs from American Petroleum Institute, American
Gas Association, and the Interstate Natural Gas Association on January 15, 2016, to discuss the
industry’s response efforts and encourage its support to SoCal Gas with technical assistance and
to ensure the industry was reviewing underground storage safety across the country.
14 40 CFR Part 300. The NCP, which is authorized by the Comprehensive Environmental Response,
Compensation, and Liability Act (CERCLA), the Clean Water Act § 311, and the Oil Pollution Act of 1990 (OPA),
provides, among other authorities, an organizational structure and procedures, known as the National Response
System (NRS), for responding to discharges and substantial threats of discharges of oil and substantial threats of
releases of hazardous substances, pollutants, and contaminants. 15 The NRS is an organized network of agencies, programs, and resources with authorities and responsibilities
in oil and hazardous materials preparedness and response at the local, state, tribal, territorial, insular area, and
Federal levels. Key federal response components of the NRS include the National Response Center, Federal On-
Scene Coordinators (FOSCs), 13 Regional Response Teams (RRTs), and the National Response Team (NRT). The
RRTs and NRT are key regional- and national-level multiagency coordination groups, led by the EPA and
Department of Homeland Security/US Coast Guard (DHS/USCG), which provide support to the FOSC as needed
during incidents, including interagency technical assistance and resource support. The RRTs and NRT include
representatives from 13 additional Federal agencies that provide oil and hazardous materials expertise and support,
and some have specific responsibilities for natural resource protection. The two principal components of the RRT
mechanism in the NRS are a standing team, which consists of designated representatives from each participating
federal agency, state governments and local governments (as agreed upon by the states); and incident specific teams
formed from the standing team when the RRT is activated for a response. On incident specific teams, participation
by the RRT member agencies will relate to the technical nature of the incident and its geographic location. (40 CFR
§ 300.115).
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Starting on January 20, 2016, PHMSA’s Office of Pipeline Safety Emergency Support
and Security Division began leading an ad-hoc Federal Government information exchange
group. The group included career representatives from the EPA (HQ and Region), DOE,
DOI/BSEE, and PHMSA. The group met on a weekly basis until it was confirmed that the well
was permanently sealed. PHMSA provided an in person briefing for the Senate Climate Change
Task Force on January 20, 2016.
On February 5, 2016, PHMSA published an advisory bulletin entitled “Safe Operations
of Underground Storage Facilities for Natural Gas.” The bulletin reminded all owners and
operators of underground storage facilities used for the storage of natural gas (as defined in 49
CFR Part 192) to consider the overall integrity of the facilities to ensure the safety of the public
and operating personnel, and to protect the environment.
Public Meeting with State Leadership
On January 15, 2016, the State of California convened a public meeting in Porter Ranch.
In attendance were a number of state leaders, representatives of EPA Region 9, and
approximately 1,200 community members.16 The state leaders gave an overview of their
agencies and authorities, and described the actions their agencies had taken thus far in the
response to the gas leak at Aliso Canyon, including issuing orders to SoCalGas that required
abatement of the leak and relocation of residents, establishing air monitoring stations, estimating
the amount of methane being released and requiring SoCalGas to maximize withdrawals of gas
from the Aliso Canyon facility. The audience asked questions about which communities were
being affected by the gas leak and how short- and long-term effects on the communities would
be addressed. Members of the public said that SoCalGas should be held responsible for
correcting the current problem, upgrading its infrastructure to prevent future releases, and
compensating the residents without a rate increase. Many in the audience said that the Aliso
Canyon facility should be closed.
Several other meetings took place between community members and agency leads during
the leak in an ongoing effort to communicate with the impacted community.
Formation of Unified Command and Bottom Kill Planning
By November 2, 2015, SoCalGas had established an Incident Command with daily
briefings about the leak at well SS-25. The Incident Commander designation revolved between
several senior officials from SoCalGas, including Jimmie Cho, Senior Vice President for Gas
Operations and Systems Integrity. It was not until January 22, 2016, that the SoCalGas incident
command transitioned into a Unified Command (UC) with Los Angeles County Fire Department
and the LADPH. As a component of the Incident Command System (ICS), the UC is a structure
that brings together the individual Incident Commanders of all major organizations involved in
the incident to coordinate an effective response, while at the same time carrying out their own
16 State leaders present included Director of the Office of Emergency Service Mark Ghilarducci, Public Utilities
Commission President Michael Picker, Natural Resources Agency Secretary John Laird, California Environmental
Protection Agency Secretary Matthew Rodriquez, California Air Resources Board Executive Officer Richard Corey,
California Energy Commission Chief Deputy Director Drew Bohen, Department of Conservation Chief Deputy
Director Jason Marshall and OEHHA Acting Director Lauren Zeise. Elected officials present included Los Angeles
City Councilman Mike Englander, State Senator Fran Pavley, State Assembly Member Scott Wilk and Congressman
Steve Knight.
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jurisdictional responsibilities. The UC links the organizations responding to the incident and
provides a forum for these agencies to make consensus decisions. This was a significant
organizational change that provided the local agencies with much greater control over on-site
actions and improved communication to the public. PHMSA and the EPA participated in daily
briefings with the UC. The CPUC ordered SoCalGas on January 21, 2016, to continue
withdrawing gas from the Aliso Canyon storage field until it reached 15 bcf of working gas. The
withdrawal of natural gas from the Aliso Canyon storage field was intended to reduce the
pressure at the field and therefore minimize the rate of the gas leak. The remaining 15 bcf of
working gas was to ensure energy reliability on high demand days. On January 23, 2016,
SoCalGas had all wells shut off from withdrawal.
On February 8, 2016, the EPA participated in a federal interagency call with PHMSA,
the DOE and the DOI. The EPA solicited technical help from well-drilling experts in DOI’s
BSEE to evaluate the drilling and bottom kill plans for SS-25. A second DRG call was held on
February 11 with the White House National Security Council staff, during which the EPA
provided information about the status of the Aliso Canyon bottom kill operation.
On February 16, the Administrator of PHMSA, Marie Therese Dominguez, and the
Secretary of DOE, Ernest Moniz, visited the Aliso Canyon release site and participated in a
government only roundtable with key federal, state, and local agencies involved in the response
to the leak at Aliso Canyon.
On February 18, 2016, DOGGR issued a determination that SS-25 had been permanently
sealed. This determination was preceded by a “soft touch” encounter between the relief well and
SS-25 on February 10, wireline logging and testing to make sure that the relief well was properly
oriented to conduct the bottom kill operation, a milling operation to establish communication
between the relief well and the target well and pumping in mud and cement to seal the well.
The UC for the Aliso Canyon incident stood down on February 19, 2016, when the
CPUC began its lead role in the investigation phase of the incident. On September 13, 2016,
SoCalGas agreed to pay $4 million to settle criminal charges filed by the Los Angeles County
District Attorney alleging misdemeanor violations for neglecting to report the release of
hazardous materials and releasing air contaminants.
B. Observations, Discussion and Recommendations
1. Unified Command
Observation: During the initial leak period, a number of regulatory and emergency response
agencies were involved in addressing various aspects of the leak, including public health and
environmental impacts, well-control operations, community involvement, media
communications and public outreach. However, SoCalGas was acting as the single incident
commander during this time.
Discussion: For 92 days, from discovery of the leak at well SS-25 until January 22, 2016,
SoCalGas acted as the incident commander. On January 22, 2016 SoCalGas, LA County
Fire/HazMat and LADPH formally entered into a Unified Command (UC). Entering into a UC
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earlier might have improved the response in terms of environmental and public health messaging
and communication with external parties.
Generally, during emergency responses, the responsible party (in the case of the Aliso Canyon
incident, SoCalGas) and the appropriate federal, state and local agencies should enter into a UC
when it is clear that response decisions will affect multiple jurisdictions in terms of statutory
authority, functional responsibility, or material or significant impacts. In this situation, the UC
appropriately included SoCalGas, LA County Fire/HazMat and LADPH. The command structure
could have also included representatives from DOGGR, CPUC, CalEPA, and SCAQMD as
cooperating agencies. In the Aliso Canyon response, establishing a UC brought safety, logistics,
management, cooperating agency and planning elements into the ICS organization. Including
additional partners would ensure that the relevant agencies are sharing other appropriate
information with the UC and conferring/cooperating before taking independent action. Entering
into a UC earlier, with the participation of relevant cooperating agencies, would have enabled
clearer and more consistent communication among the agencies and with the public about the
progress in understanding the potential public health impacts of the release.
Recommendation: A Unified Command should be formed early in response to a natural gas
release, when human health and environmental threats are present and multiple jurisdictions are
involved in the response effort. These jurisdictions could be represented by geographical
boundaries, government levels (e.g., federal, state, local, tribal), functional responsibilities (e.g.,
fire, oil spill, emergency medical services), statutory responsibilities (e.g., Federal Land
Managers, Responsible Party) or some combination thereof. The Unified Command should
identify a liaison to the affected communities to ensure direct communication with affected
residents.
2. Expert Advisory Group
Observation: SoCalGas mobilized crews and equipment immediately upon discovery of the leak
and, within 24 hours, determined that its standard procedures to abate leaks were not working
and called in additional experts. Within 48 hours, SoCalGas had well-control experts on-site.
Discussion: EPA Region 9 staff made several visits to the SS-25 well site and participated in a
number of meetings with state and local agencies and other federal agencies, as well as meetings
that included SoCal Gas representatives. EPA Region 9 staff also consulted with an ad-hoc
federal interagency group that included DOT/PHMSA, DOI/BSEE, DOE and EPA headquarters
offices, including the Office of Research and Development and the Office of Land and
Emergency Management. EPA Region 9 found that by the time it became involved, SoCalGas
had brought in the needed well-control experts for advice on how best to control well SS-25.
However, in any potentially adversarial situation, it is helpful for regulators to have objective
advice from their own experts who can advise on the potential pitfalls from a specific course of
action. For example, the DOI/BSEE drilling engineers that EPA consulted with were invaluable
in advising on the efficacy of SoCalGas' bottom kill plan, as they had a wealth of experience
from their work with oil and gas drilling in the Gulf of Mexico.
The issues under consideration during the Aliso Canyon incident were complex and wide-
ranging and included subjects such as well-control techniques, public health effects of exposure
to mercaptans or other chemicals, the environmental impact of a greenhouse-gas release of this
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magnitude, public communication and regulatory oversight. It is essential that decision makers
have access to accurate and complete information to make well-informed decisions. A readily
accessible group of subject-matter experts might have improved the decision making process.
This is especially true for the complex engineering and health and safety issues associated with
top kill attempts and surface gas collection.
Recommendation: In jurisdictions with significant natural gas storage, facility operators,
regulatory and other responding agencies should consider compiling and maintaining a roster of
potential subject-matter expert advisors. The Unified Command could consult the roster to
quickly convene a group to provide decision makers with advice on complex technical issues.
Such an advisory group would be separate from the technical experts that are a normal
component of the typical Incident Command System.
3. Regulator Coordination and Regulatory Authority Review
Observation: In the Aliso Canyon incident, local and state agencies in California had an existing
regulatory framework and adequate authority and expertise to respond effectively to the incident.
Federal agencies provided additional expertise and support for the state response efforts.
However, this is not true across the country or for interstate gas storage facilities. This lack of
uniformity prompted Congress, PHMSA, the gas storage industry, and state regulators (generally
oil and gas boards) to examine the need for federal and state regulators to work together more
closely to produce a more effective and seamless set of safety standards and regulations.
Discussion: Federal agencies such as the EPA and PHMSA have assessed their respective
regulatory and injunctive authorities. It was determined that in this case, state and local
authorities were fully engaged, had adequate authority, and were ordering similar relief to what
federal authorities would have pursued.
However, in the event of a release from an interstate facility or in other states, there is currently
no set of mandatory safety standards that can be uniformly enforced across the country. Under
PHMSA’s state certification program for intrastate gas pipelines, states voluntarily file annual
certifications with PHMSA, representing that they have the adequate authority and resources to
effectively inspect intrastate pipelines and enforce the applicable requirements. This state
certification program is currently in place in 48 states, under which program PHMSA monitors
state programs and provides federal funding. To the extent state oil and gas agencies other than
the state pipeline safety agency will be responsible for the wells and downhole facilities, these
agencies may also need to become certified. In June 2016, Congress directed PHMSA to move
forward expeditiously with adopting minimum safety standards for underground storage, a
process which is currently underway. In addition, other federal agencies may need to fill gaps
and order additional relief to ensure that public health and the environment are protected.
Recommendation: Regulatory agencies at federal, state, and, as appropriate, local levels should
review their existing authorities and regulations related to natural gas storage facilities to identify
potential gaps and to address them in a collaborative manner that builds upon the existing state
certification program for intrastate gas pipelines.
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III. Ambient Air Pollutant Monitoring During the Incident and Public Health Risk Assessment
A. Summary of Air Monitoring Actions and Health Risk Assessment
The responding parties needed to understand what pollutants were emitted during the
period of the leak, and at what concentrations, in order to assess possible effects on public health.
Air quality monitors were deployed and data were collected, quality assured, and analyzed. The
data were then made available to public health experts for comparison with known health
benchmarks to assess the potential health risks to the exposed population. This section first
summarizes the actions taken to measure the concentrations of ambient air pollutants during the
period of the leak and then summarizes the actions taken to interpret these data in terms of health
risk.17
State and local air pollution control agencies have the primary responsibility for
conducting ambient air monitoring within their jurisdictions, including monitoring for
emergency response. The EPA provides funding and oversight to enable these agencies to
accomplish these objectives. The two air pollution control agencies that conducted emergency
ambient air monitoring in response to the Aliso Canyon natural gas leak were SCAQMD and
CARB. SoCalGas and the Los Angeles Unified School District (LAUSD) also collected ambient
air samples on facility property and in the Porter Ranch community. Later during the response,
and on its own initiative, the University of California at Los Angeles (UCLA) conducted ambient
air monitoring.
Discrete Sampling
A series of discrete sampling efforts was conducted beginning on October 26, 2015. The first
samples were taken by SCAQMD in direct response to the first community complaints received
on October 24, 2015, the day after the leak was detected. Following this initial sampling,
numerous other samples were taken for a wide variety of pollutants. In addition to the discrete
sampling, continuous monitoring was established for a small set of pollutants at fixed monitoring
sites, which is described in the next section (see Figure 1 for a map of SCAQMD and CARB
sampling and monitoring locations).
The monitoring objectives for the ambient air monitoring of pollutants were generally
threefold: (1) to assess potential exposure to various pollutants determined to be of concern, (2)
to evaluate the extent of the emissions transport into the surrounding area, and (3) to provide
information to Porter Ranch community members. One study monitored air quality at twenty
schools in the area near the leak to assess students’ exposure to pollutants of concern associated
with the leak. Most of the sampling was done in and around the Aliso Canyon Facility but
17 We note that monitoring can serve different purposes. This report addresses monitoring that was conducted
to assess human exposure to chemicals emitted by the leak as well as the environmental impacts associated with
escaping GHG emissions. The report covering the physical integrity of natural gas storage facilities addresses
monitoring for the prevention, detection, and repair of leaks at natural gas storage facilities.
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monitoring was also conducted in a separate area in order to re-verify potential pollutants of
concern within the community compared to a background location.18 Finally, indoor air was also
sampled for radon to determine whether levels exceeded EPA’s action level, due to concerns
about the potential presence of radon in the released natural gas.
The monitoring methods described in this section include:
Instantaneous grab samples19 and 12- and 24-hour canister samples that can collect
over 50 volatile organic compounds (VOC), semivolatile organic compounds
(SVOCs), polycyclic aromatic hydrocarbons (PAHs), metals, carbon monoxide,
carbon dioxide, methane, ethane, non-methane non-ethane organic carbon, and sulfur
species. Samples can be collected with canisters or Tedlar bags.
Liquid scintillation activated charcoal canisters, which can be used to measure radon.
18 https://www.alisoupdates.com/1443738525764/Facility-Supplemental-Sampling-Summary__02_15.pdf 19 Also referred to as short-term air samples, instantaneous grab samples are typically 10-minute samples used
to assess air quality at a particular point in time, thus giving a very time resolved understanding of the
ambient air, which then can be used to address specific community complaints or concerns.
NGSS Task Force: Health and Environment Report
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Figure 1: SCAQMD and CARB Sampling/Monitoring Locations20
The detailed information on the collection and analysis of the canister, tedlar bag, radon,
and instantaneous grab samples described above is summarized in Table 1.
20 Source: Aliso Canyon Facility Monitoring Network Plan, p.3
NGSS Task Force: Health and Environment Report
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Table 1: Summary of Sampling Methods and Analysis
Agency/
Location (#
Sites)
Sample
Date(s) /
Duration
Sample
Method
Pollutants Analytical Lab Analytical
Method
SCAQMD /
Porter Ranch
Community
(10)
10/26/15 –
2/4/16
Instantaneous
grab sample
SUMMA
canisters21
VOCs, methane,
CO, CO2, ethane
SCAQMD EPA TO-
1422, EPA
TO-1523,
EPA Method
25.124
SCAQMD
Instantaneous
grab sample
Tedlar
bags25
Sulfur species SCAQMD SCAQMD
Method 307-
9126
SoCalGas /
Aliso Canyon
facility
property (14)
and Porter
Ranch
Community
(24)
10/30/15 –
3/19/16
Instantaneous
grab sample
SUMMA
canisters
VOCs, methane,
sulfur species
Atmospheric
Analysis and
Consulting Inc
(AtmAA)
EPA TO-15,
modified
EPA 1827
LAUSD /
Schools near
Porter Ranch
Community
(20)
11/30/2015 –
2/22/2016
8-hour and
instantaneous
grab sample
SUMMA
canisters
VOCs, methane,
sulfur species
Quantum
Analytical
Services Inc
SCAQMD
Method 307-
91, EPA-18,
EPA Method
TO-14
LAUSD /
Classrooms
and offices in
Porter Ranch
Community
and Castlebay
Lane Elem.
School (50)
12/4/2015 –
12/10/2016
Liquid
scintillation
activated
charcoal
canisters
Radon Accustar
Laboratory
SCAQMD / 12/17/2015 aromatic
volatiles, total
21 Stainless steel containers that are under vacuum and when the valve is opened, the air sample is drawn into
the canister 22 https://www3.epa.gov/ttnamti1/files/ambient/airtox/to-14ar.pdf 23 https://www3.epa.gov/ttnamti1/files/ambient/airtox/to-15r.pdf 24https://yosemite.epa.gov/R9/R9Testmethod.nsf/0/5832DB3C67E181A78825709300656AF6/$file/200510011
2745767394902STOG6GXPND.pdf 25 teflon/milar bags that are filled with air using a small pump 26 http://www.aqmd.gov/docs/default-source/laboratory-procedures/methods-procedures/307-91.pdf?sfvrsn=2 27 https://www3.epa.gov/ttn/emc/promgate/m-18.pdf
NGSS Task Force: Health and Environment Report
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Agency/
Location (#
Sites)
Sample
Date(s) /
Duration
Sample
Method
Pollutants Analytical Lab Analytical
Method
near well SS-
25 (1)
Instantaneous
grab sample
volatiles for
carbon (C3 to
C12)
SoCalGas /
Various
locations
around Aliso
Canyon
facility and
fenceline
1/2015 –
3/2016
12-hour
6.0 liter
Silonite
canisters
VOCs, methane,
sulfur species
ALS
Environmental
EPA TO-328,
EPA TO-15,
ASTM D
5504-1229.
SoCalGas /
Aliso Canyon
facility
1/19/2016
7-day
Radon ALS
Environmental
SoCalGas /
Aliso Canyon
facility (3)
1/2015 –
3/2016
12-hour
6.0 liter
Silonite
canisters
VOCs, SVOCs,
PAHs, metals
ALS
Environmental
EPA TO-15,
EPA TO-
1330, and
EPA 602031
UCLA /
Porter Ranch
Community
(23) and
background
(1)
1/13/2016 –
1/28/2016
VOCs, gaseous
contaminants,
and size-fraction
particles
SoCalGas
2/3/2016
12-hour 6.0 liter
Silonite
canisters
VOCs, methane,
sulfur species,
ALS
Environmental
EPA TO-3,
ASTM D
5504-12, and
EPA TO-15
SoCalGas
3/3/2016
24-hour 6.0 liter
Silonite
canisters
VOCs ALS
Environmental
EPA TO-3
and TO-15
Each monitoring entity was responsible for reporting its own data. All agencies were
committed to providing results to the public quickly and in a transparent and understandable
way. Results from the SCAQMD samples were posted on its website as soon as the laboratory
analysis was complete, within two to four days after sampling.32 The results from SoCalGas
28 https://www3.epa.gov/ttnamti1/files/ambient/airtox/to-3.pdf 29 https://www.astm.org/Standards/D5504.htm 30 https://www3.epa.gov/ttnamti1/files/ambient/airtox/to-13arr.pdf 31 https://www.epa.gov/sites/production/files/2015-07/documents/epa-6020a.pdf 32 http://www.aqmd.gov/home/regulations/compliance/aliso-canyon-update/air-sampling/laboratory-results---
air-sampling-data
NGSS Task Force: Health and Environment Report
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sampling were summarized on the SoCalGas website under “air sample summary,” which
included detailed lab reports for each sample. The results for samples collected by LAUSD were
posted on the LAUSD website.33,34
Fixed Continuous Monitoring Sites
In December 2015, SCAQMD and CARB began to deploy a network of eight fixed ambient
air monitoring sites throughout the Porter Ranch community to continuously measure methane,
hydrogen sulfide (H2S), total sulfur, and benzene (See Figure 2)35 in order to develop a baseline
for various measurements and track the trends of pollutants throughout the leak event. The fixed
locations allowed the agencies to collect reliable continuous measurements that provided a useful
supplement to the discrete samples, which occurred at different locations throughout the
community and provided only a snapshot of air quality during a particular sampling period.
Methane and meteorological measurements were also collected at the SCAQMD’s Reseda State
and Local Air Monitoring Station (SLAMS)36 monitoring site, located 3.5 miles to the south.
Results from the continuous monitors were posted on the SCAQMD and CARB websites in
near-real time.
33 http://achieve.lausd.net/Page/4244 34http://achieve.lausd.net/cms/lib08/CA01000043/Centricity/Domain/135/LAUSD_Radon_Testing_Report_MD
.pdf 35 Slide 21, Federal Task Force – Aliso Canyon Presentation – June 9, 2016. Presented by Mohsen Nazemi,
P.E., Deputy Executive Officer, Engineering and Compliance, SCAQMD to the Public Health and
Environment Workgroup on June 9, 2016. 36 SLAMS monitoring sites are part of the national ambient air monitoring network that typically measure the
six criteria pollutant (Particulate matter, lead, ozone, nitrogen oxides, sulfur oxides, and carbon monoxide) in
accordance with federal regulations contained in 40 CFR part 50 and 58.
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Figure 2: Map of Fixed Monitoring Locations37
All the CARB sites were located at residential properties in the community, while the
SCAQMD sites were located at the Porter Ranch Community School (Site #3), Highlands
Community Pool (Site #4), and the Castlebay Lane Charter School (Site #6). Table 2 provides a
matrix of which pollutants were measured at each site as well as the instrument and measurement
method used for each pollutant.
37 Source: Aliso Canyon Facility Monitoring Network Plan, p.9
NGSS Task Force: Health and Environment Report
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Table 2: Summary of Fixed Monitoring Sites in the Porter Ranch Community
Site Agency Methane
Methane/Non-
Methane
Hydrocarbon
Methane/H2S Benzene Total Sulfur38
1 CARB Picarro 2301
(cavity
ringdown
spectroscopy)
n/a n/a n/a n/a
2 CARB Picarro 2301
(cavity
ringdown
spectroscopy)
n/a n/a n/a n/a
3 SCAQMD n/a Mocon
Analyzer
(FID)
Picarro G2204
(cavity ring
spectroscopy)
n/a Ecotech
(chemilumiscence)
4 SCAQMD n/a Thermo
Model 55c
(FID)
Picarro G2204
(cavity ring
spectroscopy)
n/a Ecotech
(chemilumiscence)
5 CARB LGR RMT-
200 (Off-Axis
Integrated
Cavity Output
Spectroscopy
(OA-ICOS)
n/a n/a IO
Analytical
(GC FID)
n/a
6 SCAQMD n/a Mocon
Analyzer
(FID)
Picarro G2204
(cavity ring
spectroscopy)
n/a Ecotech
(chemilumiscence)
7 CARB LGR RMT-
200 (Off-Axis
Integrated
Cavity Output
Spectroscopy
(OA-ICOS)
n/a n/a IO
Analytical
(GC FID)
n/a
8 CARB Picarro 2201i
(cavity ring
spectroscopy)
n/a n/a n/a n/a
Additionally, 24-hour integrated canister samples were collected at the three SCAQMD fixed
sites (sites #3, 4, 6) and an additional nine locations throughout the area. Three of these
additional sites were within the SoCalGas facility, three were located on the perimeter of the
SoCalGas facility, and three were located within the Porter Ranch community. Initially,
instantaneous grab samples were also collected at the SCAQMD monitoring sites if the
continuous methane monitor at site #4 measured concentrations greater than 30 ppm or the
38 Total sulfur measurements include detection of odorizing compounds tetrahydrothiophene (THT) and t-butyl
mercaptan
NGSS Task Force: Health and Environment Report
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methane monitors at sites #3 and site #6 measured concentrations above 20 ppm. The trigger
levels were set after an evaluation of general levels compared against peak levels to ensure that
the grab samples appropriately were triggered during peak concentration hours at each
location. After February 18, 2016, when the leak had been permanently sealed, the trigger levels
were lowered to 5 ppm at all three locations to account for the drop in methane concentrations
observed in the community.30
To ensure the data collected during the SoCalGas natural gas leak were accurate and of
robust quality, both CARB and SCAQMD implemented quality assurance and quality control
checks throughout the monitoring network on a regular basis and performed on-site visits for
routine maintenance of the instruments. The continuous benzene instruments operated by CARB
received bench calibrations at CARB’s Monitoring and Laboratory Division’s (MLD) laboratory
and calibration in the field when they were installed. Similarly, continuous methane instruments
operated by CARB, were calibrated prior to deployment and instrument responses were checked
against NIST traceable standards in the field. Continuous methane instruments operated by
SCAQMD were checked with a known concentration using a certified gas cylinder and were
calibrated on a weekly basis. A week-long side-by-side comparison was also performed between
various methane instruments to check for instrument variability and potential bias between
measurements and laboratory analysis.
SCAQMD also developed an “Aliso Canyon Facility Monitoring Network Plan” that
describes current and future monitoring.39 The plan describes a phased approach (Phase 1 –
Phase IV) to the ongoing monitoring in the community with specific dates and conditions for
moving to the next phase. Generally, the move to each phase is contingent upon “continued
measurements showing typical ambient levels of pollutants” and “no other species or operational
activity to cause concern for community impacts” and is associated with a gradual reduction of
certain measurements for both the continuous monitors and 24-hour integrated samples. This
approach ensures continued measurement of various pollutants while other measurements are
discontinued if ambient concentration return to typical levels for a predetermined amount of time
and there are no changes to SoCalGas operations that would warrant continued monitoring.
Mobile Methane Monitoring
In addition to the eight fixed monitoring sites, SCAQMD operated a mobile monitoring
platform measuring methane concentrations40 in order to better characterize methane
concentrations and track emissions transport within the community and surrounding area. While
methane itself is not harmful unless it is above flammability limits or is present in such high
concentrations that it displaces the oxygen needed to breathe (generally only in confined spaces),
methane measurements throughout the community served as markers for areas with high
emissions that could potentially include other pollutants. Mobile methane measurements began
on December 21, 2015 and were performed during different times of the day under varying
meteorological conditions. Each mobile monitoring run ranged from 15 minutes to multiple
hours and generally followed a unique path throughout the area, including several measurements
39 http://www.aqmd.gov/docs/default-source/compliance/aliso-cyn/aliso-canyon-monitoring-plan.pdf?sfvrsn=4 40 LI-COR 7700 open path instrument and a Global Positioning System (GPS) mounted on a hybrid vehicle
NGSS Task Force: Health and Environment Report
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in the vicinity of the community’s schools. Mobile monitoring continued until May 7, 2016, with
29 runs occurring before the leak was stopped and 44 afterwards. Prior to deployment, a
comparative side-by-side analysis of the mobile monitoring platform methane instruments and
fixed site instruments was performed to check for instrument variability. Concentrations for each
mobile monitoring run were then mapped and uploaded to the SCAQMD website.41
Methane emissions were also qualitatively observed with a Forward Looking Infrared (FLIR)
thermal camera, which allowed SCAQMD and CARB to identify the plume of fugitive emissions
and eventual leak closure in areas near Well SS-25. As with the mobile measurements taken
within the Porter Ranch community, the FLIR images were uploaded to the SCAQMD and
CARB websites.42
Summary of Results of Ambient Air Pollutant Monitoring
Final reports from the various ambient air monitoring studies have not yet been released but
some preliminary results are available from SCAQMD43 and OEHHA.44 The collective studies
found higher levels of certain air pollutants in some instantaneous samples in the Porter Ranch
community. These same air pollutants were identified in a sample taken about 10 feet from the
SS-25 well.
The VOC concentrations did not exceed any available acute Reference Exposure Levels
(RELs), which are concentrations of chemicals in the air that the general public can be exposed
to without experiencing health problems.45 Of the VOCs, benzene levels tended to be highest and
most closely approached the corresponding acute REL. The sample with the highest levels of
benzene (3.0 ppb) and other air toxics measured by SCAQMD, out of more than 70
instantaneous community samples, was collected on October 26, 2015 on Kilfinan Street in
Porter Ranch, between Turtle Ridge Way and High Glen Way, by SCAQMD.46 Using the
concentrations from this sample, SCAQMD calculated the acute health risk as approximately
one-third of the REL. SoCalGas reported measuring the highest benzene levels (5.55 ppb) on
November 10, 2015, out of the over 1,000 instantaneous grab samples it collected through
February 13, 2016. SCAQMD and OEHHA both found the estimate of acute health risk for this
sample to be approximately two-thirds of the acute REL, still below the levels where adverse
health effects might begin to be observed.
SoCalGas also measured hydrogen sulfide in instantaneous samples in the Porter Ranch
community. The majority of these samples had concentrations that were too low to be measured,
but six community samples had detectable levels of hydrogen sulfide47. Among these six samples
41 http://www.aqmd.gov/home/regulations/compliance/aliso-canyon-update/air-sampling/xxx 42 https://www.arb.ca.gov/research/aliso_canyon/images/aliso_canyon_images_video.htm 43 http://www.aqmd.gov/home/regulations/compliance/aliso-canyon-update/health-impacts-estimates 44 http://oehha.ca.gov/air/general-info/aliso-canyon-underground-storage-field-los-angeles-county 45 RELs do not include consideration of cancer, which is evaluated using other methods. Exposure to a
concentration that is higher than its REL does not necessarily cause health problems, because the RELs are based on
several substantial uncertainty factors. A list of OEHHA Acute, 8-hour and Chronic RELs can be found here:
http://oehha.ca.gov/air/general-info/oehha-acute-8-hour-and-chronic-reference-exposure-level-rel-summary 46 http://www.aqmd.gov/home/regulations/compliance/aliso-canyon-update/air-sampling/laboratory-results-
--air-sampling-data 47 The sample detection limit (SDL) is equal to the Detection Limit (1.58 ppbV) x Canister Dilution Factor X
Analysis Dilution Factor. For most samples the SDL is approximately 3 - 4 ppb.
NGSS Task Force: Health and Environment Report
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with detectable concentrations of hydrogen sulfide, five samples had concentrations well below
the acute REL of 30 ppb, and only one instantaneous grab sample (collected on November 12,
2015) exceeded the acute REL. This air sample contained a hydrogen sulfide concentration of
183 ppb. The only other sulfur-containing compound detected to date in the Porter Ranch
neighborhood was a sulfur dioxide level of 54 ppb at the same location on the same day. While
detectable, this was still below the sulfur dioxide acute REL of 250 ppb and below the EPA’s 75
ppb 1-hour National Ambient Air Quality Standard for sulfur dioxide. These elevated levels of
hydrogen sulfide and sulfur dioxide were not detected in other samples.
The majority of hourly methane levels measured at the fixed monitoring sites operated by
CARB and SCAQMD were below 30 ppm. The highest hourly methane level measured at one of
these sites was 96 ppm, observed on February 11, 2016, just prior to final well kill operations.
While elevated, SCAQMD and CARB do not consider these levels to be a health concern.48,49
Sampling conducted by researchers from UCLA’s Fielding School of Public Health did not
show significant elevation of the contaminants evaluated. In their preliminary evaluation of the
data, however, the fine and ultra-fine particulate fractions downwind of Well SS-25 in the
community appeared to be atypical in terms of particle size distribution compared to those
sampled at other control locations.
LAUSD’s radon study found that all indoor radon gas levels were determined to be below
EPA's action level of 4.0 pCi/l. LAUSD’s school sampling for other pollutants of concern found
that sampled pollutant concentrations were below relevant thresholds of health concern.50
In summary, agencies including LADPH, OEHHA, and SCAQMD reviewed the SCAQMD
and SoCalGas data to determine if there were public health risks associated with exposures to the
measured air pollutants. The measured concentrations of air pollutants were below relevant
thresholds of concern, except where noted above. More detailed information on the Aliso
Canyon health risk assessments are provided in a following section.
Air Quality Criteria
On February 16, 2016, CARB and SCAQMD issued a joint memo titled “Criteria for
Determining when Air Quality in the Porter Ranch and Surrounding Communities Has Returned
to Typical (Pre-SS-25 Leak) Levels,” which outlined the criteria that would be used to determine
when concentrations of methane, hydrogen sulfide, mercaptans, benzene, and public nuisance
complaints had returned to typical levels (see Table 3).51
48 There are no specific exposure limits for Methane. Methane is primarily an asphyxiant, particularly when
concentrated in confined spaces. Its primary health effects relate to its flammability as well as its ability to displace
oxygen in certain situations within enclosed structures. The levels found in the community were far below the
concentrations that would cause oxygen displacement. Levels of methane found in the community were substantially
lower than flammable limits (50,000 ppm). 49 http://www.aqmd.gov/home/regulations/compliance/aliso-canyon-update/air-quality-criteria 50 http://www.publichealth.lacounty.gov/media/docs/AlisoAir.pdf 51 http://www.arb.ca.gov/research/aliso_canyon/aliso-canyon-criteria-description.pdf
NGSS Task Force: Health and Environment Report
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Table 3: Summary of Ambient Air Criteria used for Determining Typical (Pre-SS-25 Leak)
Pollutant Levels
Pollutant of Concern Ambient Air Criteria
Methane No grab sample concentration > 5ppm
No hourly average concentration > 4 ppm
No 12-hour or 24-hour average concentration > 3 ppm
Hydrogen Sulfide No concentrations > 10 ppb
Mercaptans No concentrations > 5 ppb
Benzene No 1-hour average concentration > 2 ppb
No 12-hour or 24-hour average concentration > 1 ppb
Public Nuisance No public nuisance related to mercaptan odors in Porter Ranch or
surrounding communities
According to the memo, continuous measurements of these pollutants were to be collected
and uploaded to both CARB and SCAQMD websites with direct comparison to the criteria
established above.52 As outlined in SCAQMD’s monitoring plan, these measurements will
continue until January 31, 2017. The application of these criteria to the monitoring data are
discussed in the section that immediately follows.
Ambient Air Pollutant Health Risk Assessment and Communication
As samples were collected to determine the ambient concentration of various chemicals in
the air, agencies including the LADPH, OEHHA and SCAQMD reviewed the collected
monitoring and sampling data to determine if there were public health risks related to pollutants
emitted from the leaking well. This section summarizes the actions each of these agencies took to
assess and communicate the potential ambient air pollutant health risks associated with the Aliso
Canyon natural gas leak.
On October 28, 2015, five days after the leak was discovered, LADPH was asked by the LA
County Office of Emergency Management to assess whether the leak could be adversely
affecting the health of nearby residents. On November 19, 2015, the LADPH issued a Public
Health Directive to SoCalGas, along with its first Preliminary Environmental Health Assessment
based on its review of available environmental and health data at the time. 53 The directive
ordered the gas company to continue the abatement process, eliminate odorous emissions and
provide free, temporary relocation to residents who chose to relocate. The preliminary health
assessment advised that “methane gas itself poses little direct health threat upon inhalation in an
outdoor space. Mercaptans, however, do pose a health threat to the community, including short-
term neurological, gastrointestinal, and respiratory symptoms that may result from inhalation.”
The assessment went on to state that exposures to these pollutants would not constitute an
immediate danger to life and that permanent or long-term health effects were not expected. Since
52 http://www.aqmd.gov/home/regulations/compliance/aliso-canyon-update/air-quality-criteria and http://www.arb.ca.gov/research/aliso_canyon/aqcriteria.htm
53 http://publichealth.lacounty.gov/eh/docs/AlisoCanyon.pdf
NGSS Task Force: Health and Environment Report
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the publication of that preliminary health assessment, LADPH went on to publish a number of
reports summarizing the results of the SoCalGas monitoring data.54
On December 18, 2015, the Office of the Governor issued a letter to the Chief Executive
Officer of SoCalGas Company, noting that the Governor had directed numerous state agencies to
take action investigating the well and the public health concerns surrounding the leak.55 The
letter indicated that OEHHA had been monitoring health concerns in the local community. In the
Governor’s January 6, 2016 Proclamation, he noted that OEHHA had been reviewing the
SoCalGas air quality measurements, evaluating public health concerns from the gas leak and
assisting other state agencies in determining whether additional actions were needed beyond
those already required by local public health agencies. The proclamation also requested OEHHA
to convene an independent panel of scientific and medical experts to review public health
concerns stemming from the gas leak and evaluate whether additional measures were needed to
protect public health beyond those already put in place.
OEHHA’s assessments of health risk were provided on a regular basis after the Governor’s
proclamation and were updated as new information became available (e.g., when additional
sampling data were available and to account for the expansion of sampling to cover additional
locations, pollutants, and averaging times). To conduct its assessment, OEHHA compared the
measured peak concentrations to acute RELs to evaluate potential effects due to short-term
exposures.56 OEHHA also compared longer-term average benzene exposures to chronic RELs,
though chronic RELs are typically used to evaluate exposures that last at least eight years.
One of OEHHA’s earliest health risk assessments, from January 14, 2016,57 concluded:
Overall, the available air sample data did not indicate that an acute toxicity health hazard
existed in the Porter Ranch neighborhood as a result of the Aliso Canyon natural gas leak.
This did not mean that the adverse physical symptoms reported by many Porter Ranch
neighborhood residents were not real. The natural gas odorants tert-butyl mercaptan and
tetrahydrothiophene have strong odors that can be perceived at concentrations below the
levels that can be detected in air samples. These odors can evoke physiological responses
(e.g., nausea, headaches) without inducing more serious or longer-lasting health effects,
such as eye or respiratory system damage.
The SoCalGas air samples measured levels of certain volatile organic compounds (VOCs)
and sulfur-containing compounds, including benzene, hydrogen sulfide and sulfur dioxide, all of
which are pollutants that can be harmful to human health if levels are high enough. Key findings
from OEHHA’s review of the data included:
Of the sampled VOCs, none was found to be above levels expected to result in adverse
health effects.
54 http://www.publichealth.lacounty.gov/media/gasleak/reportpress.htm 55 https://www.gov.ca.gov/docs/Aliso_Canyon_Letter_12.18.15.pdf 56 The assessment could only be conducted on pollutants for which a REL exists. 57 http://oehha.ca.gov/media/downloads/air/general-info/oehhaalisocanyonbackground01142016.pdf
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Benzene, a VOC, tended to have the highest levels, though still below levels expected to
result in adverse health effects (the highest sampled benzene concentration measured by
SoCalGas was 5.55 ppb, which is approximately 70% of the acute health benchmark,
observed on November 10, 2015, in the Porter Ranch Community).58
The levels of sulfur-containing compounds sampled in the area (hydrogen sulfide and
sulfur dioxide) were generally below detection limits and below levels expected to result
in adverse health impacts, with one exception:
o On November 12, 2015, one instantaneous grab sample of hydrogen sulfide was
above the acute health benchmark (183 ppb, which exceeds the acute health
benchmark of 30 ppb).
o This elevated concentration was not repeated in other samples and was considered
to be anomalous.
Subsequent updates to OEHHA’s health assessments did not fundamentally change as new
sampling data were collected. The latest health statement published by OEHHA on May 11,
201659 concluded:
“The symptoms reported by many Porter Ranch residents can be attributed to odorants in
the natural gas. The natural gas odorants have strong odors that can be perceived at
concentrations below the levels that can be measured in air samples. These odors can
evoke physiological responses (e.g. nausea, headaches) without inducing more serious or
longer-lasting health effects, such as eye or respiratory system damage.
Overall, the available air sample data do not indicate that an acute health hazard exists
from any of the volatile organic chemicals measured, including benzene, in the Porter
Ranch neighborhood as a result of the Aliso Canyon natural gas leak.
Current measured exposures to benzene are below the level of concern for chronic health
effects.
Benzene is a cancer-causing chemical. Any increase in cancer risk to people in the area
due to benzene emissions from the natural gas leak is likely very small. Nearly all
measured benzene concentrations in the Porter Ranch community during the leak are
similar to background levels generally found in the Los Angeles area, including at the
nearest long-term monitoring station in Burbank.”
In addition to OEHHA’s regular assessments of health risks from the SoCalGas air sampling
data, and in response to the Governor’s emergency proclamation, OEHHA convened an
“independent panel of scientific and medical experts to review public health concerns stemming
from the gas leak and evaluate whether additional measures are needed to protect public health
beyond those already put in place.”60 The independent panel, convened on January 15, 2016, was
composed of eight recognized experts from the University of California system, including
58 Collected with 12-hour canister sample 59 http://oehha.ca.gov/air/general-info/aliso-canyon-underground-storage-field-los-angeles-county#downloads.
Note that the May 11th update was issued prior to the LADPH’s indoor air assessment. See Section V for more
information about that assessment. 60 http://oehha.ca.gov/media/downloads/air/document/alisocanyonadvisorypanel01152016.pdf
NGSS Task Force: Health and Environment Report
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experts in medicine, toxicology, epidemiology and exposure sciences. OEHHA asked the expert
advisors to answer a charge question drawn from the emergency proclamation:
“Based on your expertise and your review of the information we have provided you on the
exposures of residents to constituents of the gas leak, are there additional measures needed to
protect public health beyond those already put into place?”
On February 12, 2016, the panel of advisors issued its responses to the charge question:61
“The expert advisors indicated that the measurements to date of exposures in the
Porter Ranch area to volatile organic compounds such as benzene, toluene, ethyl
benzene, xylenes, and hexane, had been largely below Reference Exposure Levels set
by OEHHA, which are protective of the general public including sensitive
individuals. The advisors noted that the measured exposures were not different than
routine human exposures to these compounds, which are found in ambient air both
indoors and outdoors. Although there were a few instances in which benzene levels
were mildly elevated for brief periods of time, the expert advisors expressed little
concern for current levels of exposure to these air contaminants from the gas leak.
The expert advisors indicated that the symptoms reported to the LADPH were largely
consistent with known responses to the noxious odors of the mercaptan odorants
added to the natural gas.
The expert advisors overall found the measures taken offering relocation and
providing air filters were effective, but they encouraged all reasonable actions to
reduce exposure to the odorants, in order to reduce the symptoms.”
The panel issued additional recommendations, such as providing resources to instruct
community members on proper filter use and giving additional guidance on community
relocations, and that some type of health surveillance study be conducted to collect information
on health effects from low-level exposures to mercaptan odorants.
SCAQMD published evaluations of the potential health impacts to the Porter Ranch
community based on its ambient air monitoring, which is described above.62 Its analysis
evaluated potential short-term and long-term health effects. Health risks were calculated using
two approaches: health risk estimated from directly measured pollutant concentrations at
monitoring locations in the community, and health risk calculated by modeling pollutant
concentrations throughout the community. The modeling analysis extended approximately four
miles into the community from the leak site.
For non-cancer risks, SCAQMD’s estimated exposures were compared to RELs established
by OEHHA. Estimates of cancer risks were also based on OEHHA methods, measured as the
chance that being exposed to small amounts of these chemicals over a specified time period
would cause cancer. SCAQMD defined “chronic exposures” to be six months long, though
actual exposure duration to air toxics while the well was actively leaking was less than six
months.
61 http://oehha.ca.gov/media/downloads/air/document/alisocynsummaryexpertadvisors02122016n.pdf 62 http://www.aqmd.gov/home/regulations/compliance/aliso-canyon-update/health-impacts-estimates
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SCAQMD concluded that the levels of community exposure to air contaminants in the
natural gas released from Aliso Canyon were not expected to cause a significant increase in
overall risk of health effects from either short-term or long-term exposure and were similar to the
levels of air pollutants typically found in outdoor air in Southern California. They also concluded
that exposures to the odorants added to natural gas (tetrahydrothiophene and mercaptan) can
cause short-term symptoms, consistent with many of the symptoms reported by some community
members. As with the OEHHA health risk assessments, SCAQMD pointed out that there are
insufficient studies available to determine the long-term effects of exposure to these odorizing
additives. SCAQMD also stated that it will continue to assess additional monitoring data as they
become available, updating the health risk assessment if substantially higher concentrations are
reported.
The LADPH also issued a series of air monitoring and health assessment reports, with the
initial report released on January 31, 2016 and supplemental reports published on February 5, 13
and 19.63 These reports summarized the data that had been collected by SoCalGas, SCAQMD
and LAUSD, and came to similar conclusions about the health risks posed by the monitored data.
For example, in the summary of the February 13 supplement, LADPH concluded, “The levels of
chemicals of primary concern (methane, odorants, and benzene) have been either non-detectable
(odorants) or consistently below levels that are associated with health effects (methane and
benzene).”
As mentioned earlier, SCAQMD and CARB jointly developed a document titled “Criteria for
Determining when Air Quality in the Porter Ranch and Surrounding Communities Has Returned
to Typical (Pre-SS-25 Leak) Levels”.64 The criteria were developed to determine when air
quality in Porter Ranch and the surrounding community returns to levels consistent with what
was typical prior to the leaking well at the Aliso Canyon natural gas storage facility. According
to the document:
“The criteria are designed for public health protection and take into consideration the
available scientific information and pollutant measurements collected to date in the surrounding
communities and elsewhere. The criteria are based on levels that are typically observed in the
outdoor air in other areas throughout the greater Los Angeles region. The criteria for benzene
and hydrogen sulfide are designed to keep those pollutants below the existing science-based
levels of health concern.”
OEHHA reviewed the Outdoor Air Criteria section of the overall criteria document and
concluded that the “criteria are scientifically valid. The residents of Porter Ranch and the
surrounding communities should not experience adverse health impacts from air quality
satisfying the criteria standards.”65 On their website, SCAQMD and CARB maintain a table that
shows whether the criteria have been met on any individual day.66 According to the website, the
table differentiates between real-time monitoring at the eight monitoring sites operated by
SCAQMD and CARB staff and samples that are collected in the field and returned to the
63 The reports can be found on the LADPH website:
http://www.publichealth.lacounty.gov/media/gasleak/reportpress.htm 64 http://www.arb.ca.gov/research/aliso_canyon/aliso-canyon-criteria-description.pdf 65 http://oehha.ca.gov/media/downloads/air/general-info/oehhaevalscaqmdarbdata.pdf 66 http://www.aqmd.gov/home/regulations/compliance/aliso-canyon-update/air-quality-criteria
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laboratory for analysis. Lab samples considered in the evaluation include those collected by
CARB, SCAQMD and SoCalGas. Since February 11, 2016, when these criteria were first
applied to the collected air data (post well closure), all lab samples and continuous monitoring
data have met their respective criteria for mercaptans, benzene, and hydrogen sulfide. The only
samples that have not met their criteria are a number of 12-hour methane samples collected by
SoCalGas that were greater than the 3 ppm criteria for methane. According to the SCAQMD
website,
“It is possible that continued off-gassing of residual methane in the soil near well SS-25 is
causing higher measurements near the facility fence line. However, the reason for the slightly
higher than criteria levels of methane at community sites located further south is unclear.
ARB and SCAQMD are investigating to determine the cause, including reviewing potential
sources and quality assurance between laboratories.”
The methane criteria were set primarily to make sure that the SS-25 well had not resumed
leaking. SCAQMD and CARB do not consider these levels to be a health concern because health
effects from methane exposure occur at levels far above the criteria level of 3 ppm.67
CARB staff also researched filtration technologies for portable indoor air cleaning devices
and in-duct filters and identified those that were most likely to be effective in removing sulfur
compounds and other chemicals likely to be in the plume. They communicated their
recommendations to SoCalGas staff. In December and January, guidance for selecting and
maintaining an air cleaner, and a list of available air cleaners that appeared to be most effective
for homes in the plume, were posted on a website CARB developed specifically for the Aliso
Canyon residents.68
B. Observations, Discussion and Recommendations
1. Monitoring Network
Observation: The network of ambient air monitors deployed in the community and facility
property was appropriate for the objective.
Discussion: Generally, the monitoring network that California state and local agencies
established after the leak was discovered provided a detailed and robust characterization of
ambient air quality in the vicinity of the SoCalGas natural gas leak and the surrounding
community of Porter Ranch. The network included:
The collection of instantaneous grab samples,
fixed monitoring locations established by CARB and SCAQMD,
SCAQMD’s mobile monitoring platform,
67 Methane is a simple asphyxiant. Its primary health effects relate to its flammability as well as its ability to
displace oxygen in certain situations within enclosed structures. The levels found in the community were far below
the concentrations that would cause oxygen displacement. Levels of methane found in the community were
substantially lower than flammable limits (50,000 ppm). 68 http://www.arb.ca.gov/research/indoor/aircleaners/air_cleaners_gas_leak.htm
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the 12-hour and 24-hour integrated samples,
monitoring commissioned by LAUSD at various schools in the area, and
monitoring conducted by SoCalGas.
The continuous ambient air monitors and sampling methodologies utilized at the fixed
monitoring locations and the mobile platform were appropriate and reliable for the monitoring
objective. All the laboratories that analyzed ambient air samples using canisters or tedlar bags
followed appropriate methodologies for characterization of the pollutants of concern.
Jurisdictions throughout the United States may not have ready access to similar resources.
Recommendation: State and local monitoring agencies with natural gas storage facilities within
their jurisdictions should have the ability to establish a robust ambient air monitoring network in
the surrounding communities in order to adequately characterize the potential health impacts
associated with natural gas leaks if resources are available. This includes access to real-time
monitoring equipment for sulfur additive compounds, VOCs (hydrocarbons and aromatic
compounds), SVOCs (e.g., naphthalene), methane, PM2.5, H2S, metals, and any other chemicals
of concern identified by source data, as well as capability for instantaneous grab and 24-hour
integrated samples.
2. Timeliness and Data Availability
Observation: Ambient air monitoring was deployed quickly in response to community concerns.
Posting of ambient air samples in near-real time helped keep the community and public health
agencies well informed.
Discussion: SCAQMD was able to initiate the collection of instantaneous grab samples on
October 26, 2015, three days after the leak was discovered, in direct response to community
complaints, providing a timely response to the community’s concerns. Additional data were
collected by SoCalGas, CARB, and LAUSD in the days that followed. All entities that collected
ambient air quality data on facility property or within the surrounding communities posted the
results on publicly accessible websites. CARB and SCAQMD specifically posted both results
from instantaneous grab and 24-hour integrated samples as well as near-real-time data from
continuous monitors at the eight fixed locations within the community. Efforts were made to
synthesize the data so that community members could understand the results.
Recommendation: State and local monitoring agencies should have an emergency air
monitoring plan established to expeditiously deploy an ambient air monitoring network if a
similar leak were to occur. Having data early in the process would enable agencies to reach
timely decisions most consistent with public health protection (such as the decision to relocate
residents). State and local monitoring agencies should also post their collected ambient air
quality data in a prompt, easily accessible and easy-to-understand way.
3. Pollutants of Concern
Observation: Pollutants of concern were not identified prior to the leak event and composition
of the kill fluids was unknown.
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Discussion: It is common practice in the petrochemical industry to “fingerprint” each petroleum
refinery’s oil. 69 This type of analysis could be conducted periodically for each natural gas
storage facility, in order to develop an understanding of what chemical compounds constitute the
gas in each facility. The “fingerprint” results could be shared and filed with local monitoring
agencies. This process could also be undertaken for any of the kill attempt fluids in order to
better understand the chemical composition of the material used and its potential impact on
public health. Having these analyses available would further enable health and air quality
agencies to develop comprehensive environmental sampling plans that can be used in the event
of a leak. These analyses would also aid in determining the scope of monitoring, sampling and
analyses required, ultimately saving valuable resources and time.
For example, with respect to the SS-25 leak, CARB deployed continuous benzene monitors at
two of the fixed monitoring locations within the community and monitored ambient levels of
benzene throughout the life cycle of the leak. Benzene was chosen out of concern for public
health, due to its known human health risks and the fact that it is present in small amounts in
natural gas.
Recommendation: State and local monitoring agencies in jurisdictions with natural gas storage
facilities should consider collaborating with those facilities to develop facility-specific chemical
fingerprints of the natural gas. If kill attempts are considered for sealing a leaking well, the kill
fluid should also be analyzed for metals and other potential pollutants of concern. Once these
chemical fingerprints are known, targeted monitoring plans should be developed in order to
facilitate a quick and targeted response to a leak event. Such a plan should prioritize sampling
pollutants of greatest health concern, which could include benzene, toluene, ethyl benzene and
xylenes (BTEX), PM2.5 and hydrogen sulfide for air sampling.
4. Background Concentrations of Pollutants
Observation: Background concentrations of methane and other pollutants of concern were not
specifically known for the areas surrounding the SoCalGas facility and well SS-25.
Discussion: While SCAQMD, CARB, LAUSD and SoCalGas performed extensive monitoring
throughout the community and on the facility’s property during the leak, there were no prior
measurements for methane, benzene, mercaptans, hydrogen sulfide, or other compounds in the
immediate area that would have established local background levels for these pollutants in the
affected communities. Without local background levels, it is inherently difficult to accurately
interpret monitoring results during the life cycle of the leak event. Fortunately, SCAQMD
periodically conducts extensive monitoring studies of air toxics in the South Coast air basin, the
most recent of which is its Multiple Air Toxics Exposure Study IV (MATES IV), released in
May, 2015. This study allowed SCAQMD to make general comparisons with previous typical
levels for some pollutants (e.g., benzene).70 Most areas are unlikely to have robust air toxics
monitoring studies that would be available for use as background data in case of a natural gas
release.
69This analysis is typically done by GC/MSD or other GC detectors using either EPA Method TO-14, Method
TO-15, EPA Method EPA-18, or Method TO-3. 70 http://www.aqmd.gov/home/library/air-quality-data-studies/health-studies/mates-iv
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Recommendation: State and local monitoring agencies should consider collaborating with
stakeholders to develop local background levels for methane and other pollutants of concern.
5. Health Effects
Observation: The full range of health risks from exposures to air pollutants released from the
leaking well is not known, including health risks that may manifest over the long term.
Discussion: OEHHA and SCAQMD investigated the acute health risks from exposures to
pollutants for which REL values existed. Chronic risks were also evaluated, though the exposure
period during the well leak was much shorter than typical chronic exposures. OEHHA searched
for REL-equivalent values for the natural gas odorants (t-butyl mercaptan and
tetrahydrothiophene), but found that there are insufficient studies available to establish a REL
and to determine the long-term effects of exposure to these odorizing additives.
SCAQMD’s independent Hearing Board approved a legal order that requires SoCalGas to fund a
health study (to be completed by a third party) of the potential health effects of exposure to the
gas leak.71 According to the order, the study will include exposure to the odorants added to
natural gas, for which there are currently no established RELs or cancer toxicity values. This
study is pending.
Recommendation: Further research is needed to determine the acute and chronic effects of
exposure to natural gas odorants (t-butyl mercaptan and tetrahydrothiophene). Relevant agencies
should review the results of the SoCalGas-funded study ordered by the SCAQMD Hearing
Board and consider any relevant findings or recommendations. Monitoring and analysis by state
and local agencies should continue and risk data should be updated if conditions change.
6. Coordination and Expertise
Observation: A breadth of local and state expertise, along with frequent interagency
coordination, aided in the assessment of air pollution-related health risks to the community.
Discussion: Beginning in November, 2015, twice-weekly calls were held to discuss air
monitoring activities, sampling results and health risk assessment with experts in those fields.
Participating agencies included SCAQMD, OEHHA, CARB, LADPH, LA County Fire/HazMat,
LAUSD, SoCalGas, and others.
Recommendation: In the event of a future well leak, responding agencies should include health-
related expertise in the response. Responding agencies should consider establishing a network of
these health and risk assessment professionals prior to a leak event. After a leak has been
identified, the network should be convened to meet regularly to assess collected air sampling
data and the potential for health impacts from related pollutant exposures.
7. Detection Methods
Observation: The analytical methods used to detect sulfur compounds were not able to identify
the ambient concentrations experienced by the community and workers at the site because of
sampling method detection limits.
71 http://www.aqmd.gov/docs/default-source/compliance/aliso-cyn/findings-and-decision-
(complete).pdf?sfvrsn=4
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Discussion: Methods ASTM D5504-12 and SCAQMD 307-91 were used to test for sulfur
compounds in ambient air. These methods were developed to test for sulfur compounds in
natural gas and/or from pollutant sources. As a result, the parts-per-billion level detection limits
of these methods were above the odor threshold for some of the sulfur-based odorants.
Additionally, the containers and holding times used may have not been adequate to prevent
significant breakdown of low concentrations of odorants prior to analysis. Methods have been
developed to sample and analyze sulfur compounds in ambient air at parts-per-trillion levels,
which are more similar to levels detected by the human nose. These methods, however, are not in
routine use for a number of reasons:
Source-test methods with detection limits in the low ppb range cannot be easily modified
to produce lower detection limits due to the reactive nature of the analytes, and
The cost and time required to implement low concentration analyses are generally
prohibitive for individual projects.
There are published low-level sulfur compound testing methods that have been used in research
studies. However, laboratories would need time and resources to prepare for analyses at these
lower detection limits. In conjunction with methane sampling, these methods could aid in
establishing leaks from natural gas infrastructure at lower concentrations and reliably discern
leaks that cannot otherwise be detected due to background methane concentrations.
Recommendation: Natural gas facilities, and local and state agencies, should consider
identifying laboratories with the capability of measuring sulfur compounds at lower detection
limits. If feasible, analytical methods to detect odorants at concentrations below odor thresholds
should be used and available during incidents.
8. Source Testing and Characterization
Observation: Source testing of emissions from well SS-25 was not comprehensive.
Discussion: Emissions from well SS-25 were not characterized for the full range of compounds
released. It would have been informative if, immediately after the release occurred, emissions of
all chemical constituents had been evaluated, followed by continuous monitoring of some
chemical constituents and periodic measurement of others. SCAQMD and SoCalGas collected a
limited number of speciated air samples near well SS-25 during the release. Characterization of
the source was limited due to safety concerns.
Recommendation: State and local air monitoring agencies should consider developing systems
to safely collect source samples during a release and consider conducting robust source
testing/characterization. Information collected on the chemical constituents of sources could be
used in conjunction with air dispersion and deposition modeling to help inform decisions.
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IV. Greenhouse Gas Emissions
A. Summary of Sampling and Results72
Significant ambient air monitoring was conducted at and around the vicinity of the Aliso
Canyon release, as discussed above. In addition to the methane data collection by CARB,
SCAQMD, LAUSD, SoCalGas and others described in Section III, a number of additional
measurement resources were deployed to quantify the methane emissions from the leak site by a
variety of state, local, and federal agencies in collaboration with several independent research
teams. These included measurements near the ground at the well site, at tall monitoring network
towers, and from airplanes and satellites. These efforts were intended to calculate the direct
emission rates in order to help estimate the total methane emissions associated with the leak.
This section will focus on the sampling of methane and the quantification of the total amount of
methane released.73
Aircraft studies
On November 5, 2015, Dr. Stephen Conley, with the University of California, Davis and
Scientific Aviation, was contacted by Tim O’Connor, Director of Climate for the Environmental
Defense Fund (EDF), to collect airborne measurements of the natural gas leak from Aliso
Canyon. SoCalGas raised safety concerns regarding the flight, and as a result the November 5
flight was aborted prior to reaching the release site. The CEC requested resumption of the flights,
and two rounds of airborne sample collection were performed on November 7 and 10.74
Subsequently, SoCalGas contracted with Scientific Aviation to conduct additional airborne
samples, and eleven additional rounds were collected.
In total, thirteen chemically-instrumented research aircraft flights were conducted between
November 7, 2015 and February 13, 2016. Aircraft transects were flown upwind and downwind
from the leaking well, confirming that there were no significant additional sources of natural gas
in the area.75 During the flights, airborne methane and ethane data were collected continuously
along cross-wind transects at multiple altitudes from 60 to 1,400 meters above ground. Ethane
72 The purpose of the greenhouse gas monitoring described in this section is to quantify the total amount of
methane released to the atmosphere. Pipeline quality natural gas, such as that stored at Aliso Canyon, is 95-98
percent methane. A small quantity of CO2 is also emitted with pipeline quality gas, but is not discussed here. The
Task Force evaluated available information and notes that the state of California is in the process of analyzing all
available data to prepare its final greenhouse gas emission estimate. 73 At the time of the Aliso Canyon release, the facility was subject to US EPA and California GHG reporting
program requirements. The facility followed the reporting program methods to report methane and CO2 emissions
from equipment leaks from valves, connectors, open ended lines, pressure relief valves, and meters. Emissions
reported to the reporting programs are calculated using well-vetted average emission factors and do not include the
full extent of the Aliso Canyon release. 74 Untitled letter report from University of California, Davis; Land Air & Water Resources, dated November 26,
2015 75 Supplementary Materials for Methane emissions from the 2015 Aliso Canyon blowout in Los Angeles, CA;
Science, Volume 351, Issue 6279; 18 March 2016
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measurements were important to distinguish the Aliso Canyon plume from non-fossil fuel
sources, where ethane would not be present, such as a nearby landfill. The data defined the
horizontal and vertical extent of the plume on each flight such that an atmospheric mass flux
could be calculated.76 Analysis of methane data from plume transects collected by Scientific
Aviation was used to estimate atmospheric methane emission rates on eleven dates throughout
the leak event plus six additional dates after the leaking well was sealed.
Based upon four airborne samples, collected over the first six weeks of the release, the
average leak rate was estimated to be 53 metric tons of methane per hour. The leak rate showed a
decreasing trend after the initial six weeks, likely due to a deliberate effort, beginning on
November 11, 2015, to withdraw natural gas to reduce the pressure in the subterranean reservoir.
The estimates collected between November 7, 2015 and February 4, 2016 were interpolated over
time to arrive at a total estimate of methane emitted from the event. In a February 2016 journal
article, Conley et al. estimated a total mass of methane released of 97,100 metric tons over the
112-day duration of the leak.77,78
On February 13, 2016, CARB publicly released its first preliminary estimate of cumulative
methane emissions from the Aliso Canyon natural gas leak based on Scientific Aviation flights
and updated estimates of hourly methane emissions. CARB released several updates to the
estimate. The April 2016 CARB preliminary estimate was 94,500 metric tons of methane.79
The Conley et al. and ARB preliminary totals do not include an estimate of the amount of
methane released after the leaking well was sealed. However, the leakage rate estimated from a
Conley flight following control of the leak by the relief well effort was more than 95% lower
than the previous, uncontrolled leakage rate.80
Several flights were made by the National Aeronautics and Space Administration (NASA)-
funded rapid response airborne surveys over Aliso Canyon with two Jet Propulsion Laboratory
(JPL) imaging spectrometers in January and February 2016. The objective of these overflights
was to differentiate between methane emissions from Aliso Canyon and other nearby sources
and to evaluate the potential for multiple surface pathways. The two instruments operate at
76 Methane emissions from the 2015 Aliso Canyon blowout in Los Angeles, CA; Science, Volume 351, Issue
6279; 18 March 2016 77 While several data sources discussed here provide uncertainty ranges on certain components of their data
(e.g., estimate for an individual day or flight), uncertainty ranges were not available from the sources for the
estimates of the total methane released by the leak 78 Methane emissions from the 2015 Aliso Canyon blowout in Los Angeles, CA; Science, 18 March 2016 79 Aliso Canyon Natural Gas Leak Preliminary Estimate of Greenhouse Gas Emissions, CARB, as of April 5,
2016 80 Aliso Canyon Natural Gas Leak Preliminary Estimate of Greenhouse Gas Emissions, CARB, as of February
13, 2016
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different wavelengths and provide complementary information81,82 These campaigns resulted in
36 independent detections and images of the methane plume at Aliso Canyon. Quantitative
retrievals of atmospheric methane column mixing ratios from the imaging spectrometer data sets
are being combined with National Institute of Standards and Technology (NIST) Large Eddy
Simulations of the leak source to test hypotheses and estimate emission fluxes. The results are
being validated against measurements of methane mixing ratios from other aircraft and surface
vehicles, surface observations of wind direction and speed, and up-looking thermal plume
imaging. Results will be published in 2016 or early 2017.
Tracer flux from instrumented vans
Under contract with SoCalGas, Aerodyne conducted a study to estimate methane emissions
by using nitrous oxide as a “tracer” in the released gas. From December 21, 2015 to March 8,
2016, Aerodyne released a known concentration of nitrous oxide near the well, then measured
the nitrous oxide and methane concentrations downwind of the site. Because the concentration of
nitrous oxide released at the well is known, and can be compared to the measured nitrous oxide
concentration downwind, that information together with co-located measured methane
concentrations can be used to estimate the concentration of methane released from the well. This
process is referred to as the “tracer flux ratio” method. Aerodyne supplemented its data set with
information from Scientific Aviation’s flights when tracer flux ratio data were not available, such
as for the period between the leak initiation and December 21st. Aerodyne found that on days
when both flight estimates and tracer flux measurements were available, the Aerodyne tracer flux
measurements were about 12% lower than the flight data. As a result, Aerodyne adjusted the
flight-based estimates down by 12% to estimate emissions for that time period. Although the
study has not yet been published, we understand the Aerodyne estimate of the release to be
86,000 metric tons of methane.83
Stored Gas Inventory Analysis
Stored gas inventory analysis is an industry standard method to determine the quantity of
natural gas in an underground storage reservoir. The basic data used for inventory analysis are
well pressures and measured volumes of gas metered into (injection) and out of (withdrawal) the
field.84 SoCalGas conducts periodic pressure checks of the reservoir, which require a complete
multi-day shutdown of the reservoir field to let the pressure equalize throughout the reservoir.
These events are referred to as “shut-ins.” SoCalGas used the most recent data from “shut-in”
events, which were done in spring and fall of 2014 and again in late February 2016 to estimate
emissions. The February 2016 shut-in inventory was done between February 19 and 29, after
81The Airborne Visible/Infrared Imaging Spectrometer (AVIRIS-C) was deployed on NASA’s ER-2 aircraft at
an altitude of about 8.6 km above mean sea level (MSL) with a ~ 7 km swath width and 7 meter surface resolution.
AVIRIS-C was able to conduct 6-8 passes per flight day for 4 days between January 12 and February 19, 2016,
providing instantaneous snapshots of the entire facility and surrounding areas. The Hyperspectral Thermal Emission
Spectrometer (HyTES) was deployed on a Twin Otter aircraft at an altitude of about 2 km above MSL with a ~ 1 km
swath width and 3 meter surface resolution. HyTES conducted mapping surveys of the Aliso Canyon facility and
surrounding areas on four days between January 14 and January 26, 2016. 82 Thorpe, et al 2016; Hulley, et al 2016; Kuai, et al 2016 83 Airborne Estimate of surface emissions, slide presentation by Dr. Stephen Conley and Ian Faloona, presented
at CARB’s Methane Symposium on June 6, 2016; http://www.arb.ca.gov/cc/oil-
gas/Conley_Presentation_ARB%20(1).pdf accessed August 3, 2016 84 Aliso Canyon Underground Gas Storage Facility - Methane Emission Estimates, SoCalGas, June 14, 2016
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well SS-25 was sealed. These pressure data were used to calculate total natural gas volumes and
to calculate the leaked methane by accounting for total injections and withdrawals. This
approach yielded a total leak estimate of 4.62 bcf of natural gas, which translates to emissions of
approximately 84,200 metric tons of methane.
Satellite observations
Satellites in orbit at the time of the leak were not designed to detect methane point sources.
However, given the unprecedented large signal associated with the Aliso Canyon methane
source, NASA-JPL requested special observations by the Japanese Space Agency’s Greenhouse
Gas Observing Satellite (GOSAT) and the Hyperion instrument on NASA’s EO-1 satellite.
GOSAT special observations of the San Fernando Valley began on Nov 13, 2015 and continued
with observation attempts twice every 3 days when skies were clear. GOSAT provides coarse
resolution (about 10 km diameter) footprints at the scale of the San Fernando Valley or LA basin
and did not resolve the source plume itself. GOSAT detected a significant, time-varying
atmospheric methane gradient in the San Fernando Valley; analysis is still underway. The
Hyperion instrument on NASA’s EO-1 satellite provides higher resolution (30 meter) imaging of
methane plumes. Hyperion data collection was successful on eight days between December 29,
2015 and February 14, 2016 with three positive detections of the main source plume (Thompson
et al 2016).85
While results from the satellites were not used to calculate a daily rate of methane emissions
that could be compared to other estimates here, the orbital observations from Hyperion were
consistent with airborne measurements made by NASA's Airborne/Infrared Imaging
Spectrometer (AVIRIS) imager.
Other relevant ongoing measurement efforts
There are several additional ongoing efforts to quantify the leak emissions: additional
methane data collected from stationary monitoring locations, remote sensing instruments,
additional aircraft measurements, and satellite data are currently being analyzed by the various
research teams in combination with advanced computational modeling efforts. These are
summarized below. Once completed, all the estimates will be published. These results, along
with the aircraft transect data, may be collectively utilized to develop a robust quantification of
the overall methane release.
Megacities Carbon Project – Measurements and Modeling
The Megacities Carbon Project (jointly funded by NIST, NASA, and NOAA with in-kind
contributions from CARB) operates a 13-node tower and roof-top based state-of-the-art
atmospheric greenhouse gas monitoring network located within and around the South Coast air
basin.86 The network has provided high-accuracy, continuous measurements of methane and CO2
mixing ratios beginning before Oct. 23, 2015. Network installation began in 2013 and the current
85 Thompson, D.R., A. K. Thorpe, C. Frankenberg, R. O. Green, R. Duren, L. Guanter, A. Hollstein, E.
Middleton, L. Ong, S. Ungar, Space-based Remote Imaging Spectroscopy of the Aliso Canyon CH4 Super-emitter,
Geophys. Res. Let. (2016), doi: 10.1002/2016GL069079 86 https://megacities.jpl.nasa.gov/https://megacities.jpl.nasa.gov/
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configuration was completed in August 2015. Two sites track relatively clean “background” air
conditions entering the basin and the outflow of polluted air from the basin (Victorville and San
Clemente Island). Every site is also equipped with one or more weather stations to help interpret
the greenhouse gas flux measurements. The Megacities framework was still undergoing
commissioning including calibration, data quality control and model validation when the Aliso
Canyon incident was reported in late October.
JPL personnel, in coordination with SoCalGas, conducted an on-site field survey of the Aliso
Canyon storage facility on November 10, 2015. The team surveyed near-surface methane mixing
ratios with two vehicles and meteorological data to support tracer-transport modeling. The team
also acquired thermal infrared video of the facility from several vantage points to evaluate the
potential for multiple surface vent pathways and area source behavior.
Another key Megacities element is JPL’s California Laboratory for Atmospheric Remote
Sensing (CLARS), located at an altitude of 5,700 feet (1,700 meters) on Mt. Wilson.87 Since
2011, the CLARS spectrometer has provided sustained observations of most of the Los Angeles
basin (typically 4-5 basin scans on clear days) with coverage that was expanded to include the
San Fernando Valley in mid-December 2015. CLARS detected significantly larger than normal
methane plumes crossing the basin during the Aliso Canyon incident.88
Solar Fourier Transform Spectrometer (FTS) measurements at Caltech and NASA-JPL
Two solar tracking FTS instruments provide historical measurements of column averaged
mixing ratios of methane, ethane and other trace gases in the atmosphere over the LA basin. The
MarkIV FTS89 has provided measurements of ethane, methane and other trace gases from the Jet
Propulsion Laboratory on roughly a weekly basis since 1985 (except during periodic field
deployments). Another FTS has been operated since 2012 at Caltech as part of the Total Carbon
Column Observing Network (TCCON). The TCCON network (largely funded by NASA) is used
to support validation of satellite observations. Ethane and methane measurements from the
Caltech and JPL FTS instruments have been used to provide a long-term assessment of natural
gas loss within the LA basin including the period covering the SS-25 leak incident.90
87 K. W. Wong, D. Fu, T. J. Pongetti, S. Newman, E. A. Kort, R. Duren, Y. Hsu, C. E. Miller, Y. L. Yung, S. P.
Sander, “Mapping CH4:CO2 ratios in Los Angeles with CLARS-FTS from Mount Wilson, California”, Atmos Chem
Phys. (2014) 14, 17037–17066, doi: 10.5194/acpd-14-17037-2014 ; Wong, K. W., Pongetti, T. J., Oda, T., Rao, P.,
Gurney, Kevin. R., Newman, S., Duren, R. M., Miller, C. E., Yung, Y. L., and Sander, S. P.: Monthly trends of
methane emissions in Los Angeles from 2011 to 2015 inferred by CLARS-FTS observations, Atmos. Chem. Phys.
Discuss. (2016), doi:10.5194/acp-2016-232 88 Flux analysis using mesoscale tracer-transport models and other methods is underway by JPL and NIST using
the Megacities tower network and CLARS to develop a near-continuous, spatially-resolved record of methane
emissions sufficient to attribute fluxes to the vicinity of the Aliso Canyon facility. These analyses will evaluate the
potential for historical methane leakage from the facility, the reported October 2015 onset of the SS-25 well leak,
the potential for highly variable fluxes associated with early top-kill attempts, and subsequent evolution of the leak
flux before and after the SS-25 bottom-kill. 89 Toon, G. C.: The JPL MkIV interferometer, Optics and Photonics News, 2, 19,
doi:10.1364/OPN.2.10.000019, 1991 90 Wunch et al 2016, Atmos. Chem. Phys. Discuss., doi:10.5194/acp-2016-359, 2016
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CARB’s Determination of Total Methane Emissions from Aliso Canyon91
On October 21, 2016, CARB released its Determination of Total Methane Emissions from
the Aliso Canyon Natural Gas Leak Incident, which documents CARB’s updated determination,
“of the total methane emissions from the Aliso Canyon natural gas leak incident and the amount
needed for full mitigation of the climate impacts”.92The State’s updated total methane emission
estimate considered studies discussed above, and additional data and analyses (such as well
pressure logs and assessment of the flow of natural gas from the reservoir to the atmosphere). It
considered two major phases of the leak and calculated emissions for both. The first phase
corresponds roughly to the first two months of the leak, a time of heightened activity at the well.
CARB’s estimate for emissions in phase 1 is 48,450 (+/- 8,810) metric tons of methane. The
second phase covers the remainder of the leak period (around 2.5 months), when less site-level
activity was occurring. CARB’s estimate for emissions in phase 2 is 51,200 (+/- 2,970) metric
tons of methane. The resulting total estimate of emissions for the duration of the leak is 99,650
(+/- 9,300) metric tons of methane.
Environmental Impacts
This methane release is likely the largest of its kind in the United States, exceeding methane
emissions from other known gas release incidents, such as those occurring at storage facilities in
Moss Bluff, TX in 2004 and Hutchinson, KS in 2001.93 For context, the radiative forcing of
about 100,000 metric tons of methane over the next 100 years is equivalent to the atmospheric
release of approximately 2.5 million metric tons of carbon dioxide using 100-year methane
global warming potential (GWP)94 or the greenhouse gas emissions of over 500,000 passenger
cars driven for one year.95,96 CARB, in its mitigation program discussed in Section VI of this
91 On October 18, 2016 DOE and PHMSA released Ensuring Safe and Reliable Underground Natural Gas
Storage, Final Report of the Interagency Task Force on Natural Gas Storage Safety, which includes a
summarization of information from the “Health and Environment” working group and specifically a preliminary
estimate of the total amount of methane released from Aliso Canyon. Subsequently, on October 21, 2016, CARB
released its updated determination which is incorporated into this report. 92 https://www.arb.ca.gov/research/aliso_canyon_natural_gas_leak.htm 93 A large release of natural gas occurred from a storage facility in Moss Bluff, TX in 2004, but most of the
methane was combusted due to an explosion and subsequent fire, and therefore emitted as carbon dioxide (not
methane) to the atmosphere. 94 Fifth Assessment Report of the United Nations Intergovernmental Panel on Climate Change (AR5), Synthesis
Report, Box 3.2 The 100-year GWP of methane is 28 in AR5, and is 25 in AR4. EPA’s Inventory of Greenhouse
Gas Emissions and Sinks notes that methane emissions from the energy sector 328 million metric tons of CO2
equivalent in 2014. 95 USEPA Greenhouse Gas Equivalency Calculator webpage; https://www.epa.gov/energy/greenhouse-gas-
equivalencies-calculator; accessed October 25, 2016 96 The concept of the Global Warming Potential (GWP) was developed to allow comparisons of the global
warming impacts of different gases. The U.S. primarily uses the 100-year GWP as a measure of the relative impact
of different GHGs. However, the scientific community has developed a number of other metrics that could be used
for comparing one GHG to another. These metrics may differ based on timeframe, the climate endpoint measured,
or the method of calculation.
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report, uses a 20-year methane GWP resulting in methane emissions equivalent to over 8 million
metric tons of carbon dioxide.97
B. Observations, Discussion and Recommendations
1. Baseline Data
Observation: The Aliso Canyon release occurred in a heavily populated region with several pre-
existing ambient air monitoring stations measuring methane and robust state and local agency
capacity to respond to threats to air quality.
Discussion: Baseline monitoring data on methane concentrations in areas with storage facilities
would greatly improve detection and quantification of leaks.
Recommendation: State and local air monitoring agencies should consider having a methane
monitoring framework. Baseline methane measurements would improve understanding of the
magnitude of a leak. The framework and measurements should build on data that are already
reported to federal/state/local agencies.
2. Release Uncertainty and Multiple Measurements
Observation: Multiple measurement techniques were employed at Aliso Canyon to estimate the
total quantity of released methane; however, uncertainties remain.
Discussion: Data from a wide variety of monitoring and measurement methods are available to
quantify emissions from the leak, including information collected through grab samples, aircraft
studies, mobile tracer flux ratio studies, satellite data, and stored gas inventory methods. Several
groups quantified emissions using various sets of these data (see Table 4). On October 21, 2016,
CARB released an estimate based on the studies discussed above and additional information and
analysis (“Updated Estimate” in Table 4 below).
Table 4: Summary of Total Methane Emission Estimates by Different Entities
Entity Data Source(s) / Description Total Methane Released
(metric tons)
Scientific Aviation Aircraft 97,100
SoCalGas Stored gas inventory
assessment 84,200
SoCalGas – Aerodyne Tracer gas flux analysis 86,000
State of California Preliminary Estimate
(Aircraft) 94,500
State of California Updated Estimate (Multiple
data sources) 99,650
97 Myhre, et al. (2013), Chapter 8, Anthropogenic and Natural Radiative Forcing, in Climate Change 2013: The
Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental
Panel on Climate Change, http://www.ipcc.ch/pdf/assessmentreport/ar5/wg1/WG1AR5_Chapter08_FINAL.pdf.
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Other natural gas storage facilities would not typically be covered by multiple existing
monitoring networks, and also may not have access to multiple measurement technologies that
are rapidly deployable to the site.
Recommendation: State and local air agencies should begin methane monitoring as soon as
possible following initial leak detection. All monitoring should be coordinated with attempts to
stop the leak in order to determine if those attempts decrease, increase or stop fugitive methane
emissions. When possible, future leaks from natural gas storage facilities should be measured
with multiple methods to confirm measurements. State and local air agencies should consider
coordination with existing measurement and quantification efforts, such as those by universities
and federal and state agencies active in methane and other air emissions monitoring efforts.
These entities may have data or experience with monitoring in the area that could be of use.
3. Measurement Technology
Observation: Rapid deployment of measurement technologies following the release helped
agencies understand the scale of the leak. Recent advancements in methane monitoring
technologies may offer less costly, more portable, and more precise measurements.
Discussion: Scientific Aviation, a company that operates aircraft modified for atmospheric
research, collected its first round of samples on November 7 because initial safety concerns
expressed by SoCalGas prevented earlier aircraft sampling. It was fortunate that the State had an
existing contract in place with the University of California, Davis that allowed it to move quickly
to initiate aircraft-based data collection. These data were used by the State to keep the public
informed as work to stop the leak was ongoing.
Entities such as DOE’s Advanced Research Projects Agency-Energy (ARPA-E) are seeking to
spur development of other advanced methane leak detection technologies that could, within ten
years, detect a broad range of leak sizes. The Environmental Defense Fund (EDF) is also seeking
to speed deployment of technologies to monitor for leaks on a continuous basis.98 On July 18,
2016, the EPA published a Request for Information inviting oil and gas owners and operators,
along with states, nongovernmental organizations, academic experts and others, to provide
information on innovative strategies to accurately and cost-effectively locate, measure and
mitigate methane emissions99. The response period ends November 15, 2016.
Recommendation: In advance of a leak, state emergency management agencies should
determine whether they have access to aircraft and/or other mobile measurement technologies
that can be rapidly deployed. Safety should be a consideration when flying in zones with high
methane concentrations. Air agencies should also consider formalizing pilot projects involving
state/local agencies, facility operators and federal agencies to deploy and evaluate some of the
evolving methane measurement methods.
98 https://www.edf.org/energy/natural-gas-policy/methane-detectors-challenge 99 Oil and Natural Gas Sector; Request for Information; Emerging Technologies, 81 FR 46670, July 18, 2016
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4. Inventory Tracking
Observation: EPA tracks greenhouse gas emissions over time using the Inventory of U.S.
Greenhouse Gas Emissions and Sinks. Many states track greenhouse gas emissions over time
using state-level inventories.
Discussion: Emissions estimates from leak events like Aliso Canyon can be incorporated into
emissions inventories if data are available. The EPA noted in the most recent Greenhouse Gas
Inventory that it plans to include the Aliso Canyon event in its estimate of 2015 and 2016
emissions, which are to be published in 2017 and 2018, respectively.
Recommendation: Studies of natural gas releases should quantify emissions in such a way that
they can be included in inventories. An emissions estimate of the total mass of gas emitted by an
event can be directly included in an inventory, while methane concentration estimates at a given
time cannot be included in an inventory without other information.
V. Post Well Closure Indoor Air and Source Sampling/CASPER Health Assessment
A. Summary
Following the closure of well SS-25 in mid-February, residents began returning to their
homes from temporary housing. From late February into March, LADPH began receiving a large
number of health complaints from the Porter Ranch community. The complaints included reports
of headache, nasal congestion, sore throat, respiratory problems, nausea, dizziness and skin rash.
Symptoms ceased when residents returned to temporary housing located outside of the area
impacted by the gas leak. This section focuses on the actions that were taken post well closure to
assess the health impacts associated with the residual impacts of the gas leak.
The reported health complaints prompted a number of separate responses. In late February
2016, Dr. M. Jerrett of the UCLA Fielding School of Public Health (FSPH) conducted indoor air
and particulate sampling in seven homes. The results of this sampling were inconclusive but
indicated the possibility of residual contamination in particulates present in homes.100 On March
14, 2016, SoCalGas began sampling the indoor air of approximately 70 homes for the presence
of methane and odorants. SoCalGas released the data on March 17, 2016, and noted that the
concentrations of these contaminants were below levels of concern in the homes they sampled.101
Then, on March 23, 2016, LADPH announced a protocol developed in conjunction with EPA
Region 9, UCLA FSPH, CARB, SCAQMD, and others for sampling the interior of homes for
residual contamination from the release. The protocol was intended to address volatile
contaminants that had been measured in ambient air during the release as well as semi-volatiles
and metals that may have been present in the geological formation or in the material used during
100 https://ehs.ph.ucla.edu/news/dr-michael-jerretts-work-porter-ranch 101 https://www.socalgas.com/1443738853622/results-of-indoor-air-screening-3172016.pdf
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the top kill attempts and released into the air. The protocol involved two phases. The first phase
was sampling the surfaces in homes using contact and wipe sampling methods, conducted from
March 25, 2016 to April 20, 2016. The second phase was sampling the indoor air inside homes,
which was conducted from March 30, 2016 to April 8, 2016.
In an effort parallel to the indoor sampling, LADPH, with the help of the California
Department of Public Health, began a Community Assessment for Public Health Emergency
Response (CASPER) health assessment on March 10-12, 2016. Initial results of this assessment
indicated that there were health issues reported that could be related to the gas leak or other
emission sources near the storage facility.102
On April 20, 2016, LADPH collected six soil samples in the vicinity of the SS-25 well to
address a data gap in the environmental sampling. Some soils near the SS-25 well were visibly
impacted by non-volatile constituents of the release. While the soil data could have been biased
by chemical breakdown, volatilization, and other weathering, it was judged as the best indicator
of chemical signatures of the release that might persist in the community. These samples
indicated elevated levels of chemicals including hydrocarbons up to C40, barium, and
naphthalene.
On May 13, 2016, LADPH released its public health assessment report titled “Environmental
Conditions and Health Concerns in Proximity to Aliso Canyon Following Permanent Closure of
Well SS-25”.103 The report presented the results of both the indoor exposure evaluation and the
CASPER health effects evaluation.104 LADPH convened experts from various local, state and
federal agencies to review and help interpret their findings. The report’s findings are summarized
below.
Indoor Exposure Evaluation
LADPH relied on testing and analysis protocols used in other environmental incidents. Using
a list of 200 chemicals potentially associated with both gas leaks and well closure attempts at
Aliso Canyon (including drilling material components), LADPH selected for analysis metals,
SVOCs, VOCs and petroleum hydrocarbons. A subset of this group was identified as priority
chemicals of potential concern: sulfur compounds, benzene and other volatile organic
compounds, barium, petroleum hydrocarbons, and polycyclic aromatic hydrocarbons. Because
reported symptoms occurred after residents returned to their homes, LADPH considered that
symptoms could be the result of exposure to indoor air or from surfaces in homes and tested for
chemical contaminants in both indoor air and household surface dust in 114 homes and two
schools. Eleven of the homes were located six miles from well SS-25 and were used as a
comparison group.
Findings:
102 http://publichealth.lacounty.gov/media/docs/assessment.pdf 103 http://www.publichealth.lacounty.gov/media/docs/PublicHealthAssessment.pdf). 104 Results are presented in Appendix A of the following report:
http://www.publichealth.lacounty.gov/media/docs/SummaryFieldSamplingReport.pdf
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Surface wipe samples: Barium was the most frequently detected metal, found in 19% of the
Porter Ranch homes. Levels of barium, aluminum, cobalt, iron, manganese, nickel, and
vanadium were higher in Porter Ranch homes than in comparison homes.
Five metals—barium, manganese, vanadium, aluminum and iron—appeared together
consistently. This consistency suggests a common source. A barium sulfate mixture was used in
three well kill attempts and there were indications that kill fluid was ejected with deposition of
barium on soil near the well.
Air samples: Levels of chemicals in indoor air of Porter Ranch homes were similar to those
found in comparison homes and were within normal ranges for home indoor air. For the priority
chemicals of concern subset, levels detected in Porter Ranch homes were lower than in
comparison homes and within normal ranges for home indoor air.
Indoor Exposure Evaluation summary:
Surface wipe sample analysis showed a pattern of barium plus other metals in Porter Ranch
homes not observed in comparison homes. This pattern is consistent with the composition of
barium sulfate drilling fluids used in well kill attempts. Indoor air analysis showed that levels of
chemicals detected were similar between Porter Ranch homes and comparison homes, and were
consistent with expected background levels in home environments.
CASPER Health Effects Evaluation
LADPH developed two survey tools to collect information on health symptoms experienced
by residents in the Porter Ranch community. The first survey tool used was a Community
Assessment for Public Health Emergency Response, or CASPER, to collect information from a
representative sample of 210 homes within a 3-mile radius of well SS-25. The CASPER survey
was conducted March 10-12, 2016. The second survey tool was a modification of the CASPER
survey directed to the approximately 100 households participating in the indoor exposure
evaluation to assess the health symptoms experienced by residents at the time of the indoor
exposure evaluation.
Findings:
The CASPER survey identified 63% of sampled households reporting health symptoms
during the month after the well was sealed. Commonly reported symptoms were eye/nose/throat
irritation (59%), headache/migraine (52%) and respiratory symptoms (51%). For the period
during the gas leak, 81% of the sampled households reported health symptoms with a similar
distribution of commonly reported symptoms. In general, households’ reported symptoms
stopped upon leaving homes, both before and after sealing the well leak. Medical care from
family physicians or urgent care centers was sought by 61% of households. Households closer to
the well reported greater frequency of health symptoms than those farther away, both during the
leak and after the well was sealed.
Of sampled households, 41% reported smelling gas odor and 35% reported oily residue on
household surfaces. Reports of health symptoms varied by whether households noticed no odor
or oily residue (43% with symptoms), odor only (53% with symptoms), oily residue only (61%)
and both odor and residue (95%). This trend was statistically significant.
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Most households (66%) reported using in-duct air cleaning devices or portable air purifiers
after well seal, with 22% of households using them intermittently and 45% of households using
them daily. More households with regular use of in-duct cleaners or portable air purifiers
reported health symptoms (62% and 74%, respectively) than did households using neither device
(45%). For households reporting gas odor and using methods to air out their home after
returning, a majority (68%) reported reduced gas odor.
CASPER summary:
The majority of households experienced health symptoms in the month following well seal.
Households closer to the well were more likely to report health symptoms or oily residue. There
was no difference in reports of gas odor in relation to well proximity. The majority of households
reported using air cleaners or purifiers.
Home Cleaning Activities
On May 13, 2016, LADPH issued a directive to SoCalGas to offer comprehensive
cleaning to all homes in Porter Ranch, all homes of relocated residents, and all homes within five
miles where residents experienced symptoms.105 This directive was followed by a May 20, 2016
ruling from the Los Angeles Superior Court that ordered SoCalGas to pay for cleaning the homes
of those households participating in the SoCal Gas relocation program. On May 25, 2016,
LADPH directed SoCalGas to implement its Interior Home Cleaning Work Plan based on
interior home cleaning guidance issued by LADPH.106 Relocated residents had until May 29 to
request cleaning, or were deemed to have declined cleaning. According to SoCalGas, all
residents who had been relocated at the time of the ruling have returned home after the
completion of interior home cleaning.107
Additional Sampling Activities
On June 22, 2016, June 23, 2016 and July 9, 2016, LADPH collected samples from
community pools in three Porter Ranch neighborhoods. Samples were analyzed for petroleum
hydrocarbons (EPA Method 8015B), Metals (EPA Method 6010B), and Mercury (EPA Method
7470A). Petroleum hydrocarbons and mercury were not detected in any of the samples. Several
metals were detected including barium ranging from 0.085 to 0.422 milligrams per liter (mg/L),
which is below the federal maximum contaminant level (MCL) for drinking water of 1 mg/L.108
According to LADPH, the purpose of this sampling was to provide guidance regarding the
collection and analysis of water from the selected community pools. The resulting data will be
used to assess potential public health impacts of the gas leak event on water quality in pools,
though no public health statements have yet been issued.
105 http://www.publichealth.lacounty.gov/media/docs/LACHODirectivetoSCG(w%20Atts).pdf 106 The SoCalGas Interior Home Cleaning Work Plan
(http://www.publichealth.lacounty.gov/media/docs/workplan.pdf) was drafted to implement the LADPH’s
Guidelines for Home Cleaning and Ventilation
(http://www.publichealth.lacounty.gov/media/docs/GuidelinesCleaning.pdf). 107 https://www.alisoupdates.com/our-commitments 108 The protocol and report are available at:
http://publichealth.lacounty.gov/media/docs/CommunityPoolWaterSamplingProtocol.pdf
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B. Observations, Discussion, and Recommendations
1. Contaminant Identification
Observation: There was a substantial effort made to identify potential contaminants associated
with the Aliso Canyon gas leak in the homes of Porter Ranch residents.
Discussion: In at least one of the top kill attempts, a significant volume of kill fluid was
expelled; it was hypothesized to be part of an oily coating found on and within many homes in
the Porter Ranch community. The results of a comprehensive effort to collect indoor air, surface
wipe and soil samples informed the response to citizen complaints, which culminated in a
comprehensive cleaning effort by SoCalGas.
Indoor air sampling results were similar to those found in comparison homes and were within
normal ranges for home indoor air. However, wipe sampling results found that a group of
metals—barium, manganese, vanadium, aluminum and iron—appeared together consistently,
suggesting a common source. Soil sampling also provided useful information regarding the
chemical constituents from the release, though since they were collected at a date later than the
indoor samples, the soil data could have been biased by chemical breakdown, volatilization, and
other weathering. The samples indicated elevated levels of chemicals including hydrocarbons up
to C40, barium, and naphthalene.
Recommendation: Given the evidence that materials used in well-kill fluids may be re-expelled
and may contaminate the surrounding area, facility operators and emergency responders should
use caution when determining the composition of the well-kill fluids and should consider the
possible health risks that might result from exposure to toxic substances present in that fluid.
Knowing the composition of the fluid would also facilitate environmental testing in the event of
an accidental release. If a situation should occur where a large volume of kill fluid or other
material is expelled along with natural gas, the appropriate state or local agency should test
exposed homes for the presence of potential or known constituents before residents return. Soil
samples taken at or near the source should be collected and analyzed for contaminants associated
with the release, especially if residues resulting from a leak are found on or within structures at
the facility or in a community and it is thought that these contaminants could pose a potential
ingestion or inhalation risk. If enough information is known about the source and the expelled
contaminants, dispersion modeling can be used to help make decisions regarding additional soil,
surface water, and indoor sampling within the impacted community.
2. Source-Receptor Evaluation
Observation: From the perspective of making the connection between the source of emissions
(well SS-25) and the locations impacted by those emissions (the “receptors,” e.g., residences,
schools, and other locations downwind from well SS-25, and ultimately the people in those
locations), the conditions of the Aliso Canyon leak were relatively straightforward. These
conditions aided the LADPH’s evaluation of the relationships between source and receptors. The
LADPH Public Health Assessment analysis also relied on the common occurrence of metals in
the source and receptor samples to indicate the connection between source and receptor. The
analytical methods used to evaluate trace metal content of residues from residences and schools
were limited to total elemental levels.
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Discussion: The conditions that allowed for a straightforward demonstration of the connections
between the source and receptors included a single, large-volume emissions source, relatively
consistent weather patterns, and fairly well-defined trace element composition of the source.
More complex situations are possible in future incidents, which could result in an inability to
adequately demonstrate the connections between the source and receptors. A lower emission rate
relative to similar surrounding sources (which may be the case with a slower leak where the
storage site is located in an operational oil and gas production area), greater variability in
weather conditions, or more complex terrain could result in substantially less confidence in the
ability to connect the source to health and environmental impacts compared to the Aliso Canyon
leak.
The metals identified as suggestive of a single source due to their common occurrence in source
and receptor samples are not unique to the sources. While it is likely that the common occurrence
of aluminum, barium, iron, manganese, and vanadium in both source and receptor samples
provides adequate evidence of well SS-25 as the source of residential and school contamination
in this case, in a more complex situation it may be more appropriate to evaluate the ratios of
various tracer species in multiple sources and receptor sites. The metals of interest here are
present in numerous sources, from crustal dust to building materials; the ratios of those trace
elements will be different for these different sources.
Recommendation: Collection and analysis of source and ambient samples should be conducted
to enable evaluations of links between receptors (such as ambient monitors and residential
surface samples), emissions from the leak, and emissions from other, nearby emission sources;
and to support evaluations of health risks associated with exposure to the mix of emitted
constituents. A more in-depth analysis of multiple relevant source trace element ratios, the ratios
of samples from receptor sites, and use of sequential extraction would be appropriate in more
complex leak situations like those noted above.
3. Post-Incident Sample Collection
Observation: The process of post-incident indoor testing was responsive to ongoing health
symptoms, yet was time consuming due to the lack of available information regarding potential
contaminants.
Discussion: Based on "oily" residues found during the release in residential areas downwind of
the SS-25, there was some evidence that residual contamination from the release may have been
persisting in the community. However, the only materials cleaned up during the release were on
outdoor surfaces, and those materials were not tested to determine if they posed a potential health
risk. Ongoing health complaints from the public and the initial evaluation of the CASPER survey
provided evidence of potential indoor exposures, at which time an indoor testing protocol needed
to be expeditiously developed and implemented. The process of preparing to sample, conducting
the sampling, laboratory analysis, and interpreting the data resulted in an effort that took several
months to complete before conclusions could be developed and shared with the community.
Recommendation: Responding agencies should plan for post-incident sample collection and
analysis, and integrate this plan into the initial incident response to help mitigate post-incident
exposures and to compress post-incident timelines.
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4. Home Cleaning
Observation: Indoor cleaning activities were completed in an inconsistent manner.
Discussion: SoCalGas used its environmental mitigation contractor to implement cleaning
activities. Many of the cleaning subcontractors did not have experience with the type of cleaning
required to mitigate residences and schools. LADPH provided significant oversight of cleaning
and was able to determine that much of the cleanings conducted were inadequate.
Recommendation: It is essential that in-home pollutant mitigation and cleaning activities only
be performed by certified professionals under adequate supervision.
5. Public Health Hazard Assessment
Observation: The LADPH Public Health Assessment notes the possibility of metals, particularly
barium, in household dust as causing symptoms observed in the CASPER survey.
Discussion: As LADPH summarized in its Public Health Assessment, barium was the most
frequently detected metal, found in 19% of the Porter Ranch homes with concentrations ranging
from 0.05 to 1.0 µg/cm2. Along with barium, four other metals (manganese, vanadium,
aluminum and iron) consistently appeared together in the Porter Ranch home samples. LADPH
noted that barium and the other metal contaminants can cause respiratory and skin irritation and
their presence could have contributed to the reported symptoms.
Although barium was the metal most commonly identified at sampling locations within the
Porter Ranch community, there are no surface wipe reference standards for barium for either
occupational or residential exposure. The absence of methods to extrapolate between surface
wipe samples and air concentrations makes it difficult to draw conclusions about human
exposures to indoor concentrations of air pollutants. Similarly, the absence of human studies or
reports that correlate a particular surface wipe concentration of metals to any health effects or
outcomes makes it difficult to draw conclusions about health impacts from those exposures.
Recommendation: State and local health and environmental agencies should consider
developing standardized approaches for collecting health information and linking it with
environmental monitoring data for use in public health hazard assessment if a similar leak event
were to occur at other well sites.
VI. Greenhouse Gas Mitigation Plan
A. Summary
Mitigation of the greenhouse gas impacts from the Aliso Canyon natural gas leak is not
required under California regulations, nor are fugitive emissions capped by California’s
economy-wide greenhouse gas cap and trade program. There are proposed state regulations in
California that would require leak detection and repair for underground natural gas storage
facilities, but these were proposed in response to the Aliso Canyon leak.
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On December 7, 2015, the City of Los Angeles filed a civil lawsuit109 in California Superior
Court in Los Angeles against SoCalGas in connection with the Aliso Canyon leak. In early 2016,
CARB joined the suit. The lawsuit includes claims alleging that methane emissions from the leak
have created a nuisance and have impaired and polluted the environment. The complaint seeks
relief relating to the leak’s climate impacts.
On December 18, 2015, SoCalGas President and CEO Dennis V. Arriola sent a letter to
Governor Brown confirming the company's commitment to “mitigate environmental impacts
from the actual natural gas released from the leak” and “work with state officials to develop a
framework that will help us achieve this goal.”
Governor Brown’s January 6, 2016 proclamation of a state of emergency ordered, among
other things, that CARB, “in consultation with appropriate state agencies, shall develop a
program to fully mitigate the leak’s emissions of methane by March 31, 2016.” The proclamation
further directed, “the mitigation program shall be funded by the Southern California Gas
Company, be limited to projects in California, and prioritize projects that reduce short-lived
climate pollutants.”
On March 31, 2016, CARB recommended a program to achieve full mitigation of the climate
impacts of the Aliso Canyon natural gas leak.110 CARB’s development process included
consultation with other state agencies and two rounds of public comment. Three areas of
concentration are recommended in the mitigation plan:
“Generate significant and quantifiable reductions in methane emissions within the
agriculture and waste sectors;
Promote a more sustainable energy infrastructure by promoting energy efficiency and
decreasing reliance on fossil fuels; and
Address emissions from methane “hot spots” not presently targeted under federal, State,
or local laws.”
CARB recommends the emission reduction offsetting component focus on reducing methane
emissions from California agriculture (including dairies) and waste (including landfills and
wastewater) that would allow for a direct ton-for-ton comparison between leaked emissions and
emission reductions from mitigation projects. CARB recommends that mitigation occur within
five to ten years from the beginning of the Aliso Canyon leak. While specific projects were not
proposed, CARB sets forth overall mitigation program objectives, project principles and specific
areas of emphasis. Implementation of the mitigation program would require additional steps
including soliciting, evaluating and selecting a portfolio of eligible projects, administering any
funds received from SoCalGas, and overseeing and potentially auditing specific mitigation
projects. CARB envisions that a mitigation program administrator would prepare and submit
periodic compliance reports that would be made available to the public. CARB notes the pending
litigation and its potential effect on any mitigation program.
109 People v. Southern California Gas Company, Los Angeles Superior Court, Case No. BC 602973 110 Aliso Canyon Methane Leak Climate Impacts Mitigation Program, CARB, March 31, 2016
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On March 24, SoCalGas submitted comments111 regarding CARB’s draft recommendations.
The comment letter notes the pending litigation and states that CARB “explicitly decided not to
regulate fugitive emissions” and “any proposed mitigation program from the ARB does not itself
impose any legal obligations on SoCalGas.” The comment letter also states that SoCalGas
intends to use its own methane emission estimate to determine the amount of emissions to
mitigate. Other comments highlight differences between the approach proposed by CARB and
how SoCalGas envisions proceeding with mitigation.
On October 21, 2016, CARB released its Determination of Total Methane Emissions from
the Aliso Canyon Natural Gas Leak Incident, which documents CARB’s determination “of the
total methane emissions from the Aliso Canyon natural gas leak incident and the amount needed
for full mitigation of the climate impacts.”112 CARB’s updated estimate indicates that the
incident resulted in a total emission of 99,650 (± 9,300) metric tons of methane. The report
states (emphasis in original), “To fully mitigate the leak, as directed by the Governor’s
Proclamation, the upper bound of this estimate should be used. Hence, the required amount of
methane that needs to be mitigated is 109,000 metric tons.”
B. Observations, Discussion and Recommendations
1. Mitigating Releases of Short-lived Climate Forcers
Observation: There are no federal or state requirements to mitigate the environmental (i.e.,
climate) impacts of methane leaks from underground natural gas storage facilities, nor are there
established standards to guide voluntary mitigation of the climate impacts of fugitive releases of
a short-lived climate forcer113 such as methane.
Discussion: There are no federal or state mitigation requirements for the fugitive greenhouse
gases released from the Aliso Canyon leak. Nonetheless, during the release, SoCalGas publicly
acknowledged the impacts it was having on the environment and voluntarily committed to
mitigating its climate impacts. Shortly after SoCalGas’ commitment, Governor Brown ordered
CARB to develop a plan to fully mitigate the leak’s emissions of methane. This combination of
corporate leadership and public agency guidance is noteworthy. However, due to the litigation
discussed in Section VI A, it remains uncertain whether the leak will be “fully” mitigated per
Governor Brown’s proclamation and mitigation will likely be affected by the court decision.
CARB’s March 31, 2016 Mitigation Program for Aliso Canyon discusses complexities
associated with mitigation and differing stakeholder opinions on approaches. For example,
methane's lifetime in the atmosphere is much shorter than that of carbon dioxide, but methane is
111 March 24, 2016 Letter from SoCalGas to CARB chair Mary Nichols re: Aliso Canyon Methane Leak
Climate Impacts Mitigation Program (Draft), dated March 14, 2016 112 https://www.arb.ca.gov/research/aliso_canyon_natural_gas_leak.htm 113 The term “short lived climate forcer” is generally used to denote a class of climate pollutants, including
methane, that have relatively shorter atmospheric lifespans and relatively stronger climate impacts compared to
carbon dioxide.
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more efficient at trapping radiation than carbon dioxide. Using the GWP metric, pound for
pound, the comparative impact of methane on climate change is approximately 28 to 36 times
greater than carbon dioxide over a 100-year period and approximately 84 to 87 times greater
over a 20-year period.114
To put this in context for Aliso Canyon, with the amount of methane to be mitigated per CARB’s
assessment (109,000 metric tons), full mitigation could be considered as ranging between
approximately 3 million to over nine million metric tons of carbon dioxide equivalent depending
upon whether one considers a 100-year or 20-year time horizon.
CARB’s plan includes offsetting 109,000 metric tons of methane, or, if the emissions of a
different greenhouse gas are reduced, to calculate equivalence using the 20-year GWP of
methane. CARB ultimately decided upon a 20-year time period for conversion into carbon
dioxide equivalents to, “…properly incorporate current scientific knowledge, underscore the
influence of SLCPs [short lived climate pollutants] as immediate climate-forcing agents and
emphasize the need for immediate action on climate change.” SoCalGas, in comments on
CARB’s approach stated, “…using the 20-year GWP in this situation is inappropriate as well as
contrary to California and federal law. Therefore, we do not intend to use a 20-year GWP as we
evaluate mitigation projects”.115
Recommendation: States with underground natural gas storage should review their legal
authorities to require greenhouse gas mitigation of fugitive emissions from underground natural
gas storage facilities. States interested in mitigation should review California’s approach as
outlined in its Mitigation Plan.
VII. Best Practices Summary
The response to the Aliso Canyon natural gas leak was without precedent and extraordinarily
complex, and it showcased a number of response actions that could be considered “best
practices.” The best practices summarized in this document could help protect public health and
the environment in the event of another natural gas leak. State and local agencies, and facility
owners and operators, are encouraged to use these recommendations to prioritize and prepare for
a similar incident. A full set of recommendations is included in the Executive Summary of this
report.
Section II describes the response to the leak and highlights the numerous well-coordinated
efforts among federal, state and local authorities. However, earlier deployment of a Unified
Command in the ICS structure, and the presence of an expert advisory group, would have
supported decision making and improved public health messaging and community outreach.
State and local authorities may consider creating an expert advisory group that could be
convened by the Unified Command in the event of an incident to provide advice and input on
114 Fifth Assessment Report of the United Nations Intergovernmental Panel on Climate Change (AR5),
Synthesis Report, Box 3.2 115 Letter from SoCalGas to CARB chair Mary Nichols re: Aliso Canyon Methane Leak, Climate Impacts
Mitigation Program (Draft), dated March 14, 2016
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complex technical issues. Responsible parties can study the many techniques that were used to
kill the SS-25 leak to inform their future decisions in similar incidents.
The air quality monitoring effort, described in Section III, provided the public and
responding agencies with near-real-time information about pollutants of potential concern. These
monitoring strategies and techniques can serve as a template for monitoring responses should a
similar natural gas leak occur elsewhere. Areas with natural gas storage facilities should have the
capacity to establish similarly robust air quality monitoring in order to adequately characterize
the public health impacts of a release. State and local monitoring agencies should consider
developing an emergency air monitoring plan to expeditiously deploy a health-based ambient air
monitoring network if a leak occurs. If the chemical fingerprint of the natural gas and other
potential materials associated with well maintenance or kill attempts are known, the air quality
monitoring and environmental sampling plans can target the sampling of pollutants of greatest
health concern. Air monitoring plans should include analyses for sulfur compounds at detection
levels lower than the parts per billion range to better characterize the population’s exposure to
sulfur and odorants. Responding health and environmental agencies should also review the
results of any future health-related studies (e.g., health surveillance, epidemiological, etc.)
related to the Aliso Canyon leak and consider any relevant findings or recommendations.
Similar to the quick deployment of ambient air monitoring resources, efforts to measure and
quantify the amount of methane leaking from the well were deployed quickly, as described in
Section IV. The Aliso Canyon release occurred in a heavily populated region with many pre-
existing ambient air monitoring stations and robust regulatory capacity to respond to threats to
air quality. Access to measurement resources, such as monitors, airplanes and satellites, aided in
this response. If a similar natural gas leak were to occur elsewhere, having an air monitoring
framework in place would be key to understanding the magnitude of leaks quickly.
In response to complaints received from residents who returned home once the well was
closed, the LADPH conducted an assessment of the indoor environment in Porter Ranch homes
as well as a Community Assessment for Public Health Emergency Response (CASPER) health
assessment. The results of these studies, which found elevated levels of specific metals as
summarized in Section V, led LADPH to direct SoCalGas to pay for professional cleaning of
nearly 2,500 homes. Significant resources were required to undertake post-well closure analyses
to identify potential contaminants in the homes and to conduct the CASPER community health
assessment. LADPH’s efforts to conduct these assessments provide a useful template for other
responding agencies to follow if faced with a similar situation. If a situation should occur where
a large volume of kill fluid is expelled along with natural gas, exposed homes should be tested
for the presence of known kill fluid constituents before residents return. In addition, potential
resources should be identified in advanced to cover the costs of source sampling and assessment.
As discussed in Section VI, although not required by federal or state regulations, SoCalGas
committed to “mitigate environmental impacts from the actual natural gas released from the
leak” and “work with state officials to develop a framework that will help us achieve this goal.”
However, the lack of standards to guide voluntary mitigation of methane coupled with multiple
lawsuits have created uncertainty regarding the final outcome of mitigation. If a similar leak
occurs elsewhere, it is unclear whether comparable quantification capabilities would be
available, since other natural gas storage facilities may not be covered by existing monitoring
networks and may not have access to multiple, rapidly deployable measurement technologies.
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States with underground natural gas storage should review their legal authorities to require
greenhouse gas measurement and mitigation of fugitive emissions from underground natural gas
storage facilities. States interested in mitigation should review California’s Mitigation Plan.
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List of Acronyms
ARPA-E – Advanced Research Projects Agency - Energy
AVIRIS-C - Airborne Visible/Infrared Imaging Spectrometer
bcf – Billion Cubic Feet
CARB - California Air Resources Board
CA ISO - California Independent System Operator (California ISO)
Cal/OES - California Office of Emergency Services
CEC - California Energy Commission
CLARS - California Laboratory for Atmospheric Remote Sensing
CPUC - California Public Utilities Commission
CAA - Clean Air Act
CWA - Clean Water Act
CASPER - Community Assessment for Public Health Emergency Response
CERCLA - Comprehensive Environmental Response, Compensation and Liability Act
DHS/USCG - Department of Homeland Security/United States Coast Guard
DOC –Department of Commerce
DOE - Department of Energy
DOGGR - California Natural Resources Agency/Department of Conservation//Division of
Oil, Gas and Geothermal Resources
DOI - United States Department of Interior
DOI/BSSE - DOI/Bureau of Safety and Environmental Enforcement
DOT/PHMSA - United States Department of Transportation/Pipeline Hazardous Materials
Safety Administration
DRG - Domestic Resilience Group
EDF – Environmental Defense Fund
EPA - United States Environmental Protection Agency
FOSC - Federal On-Scene Coordinator
FEMA - Federal Emergency Management Agency
FLIR – Forward Looking Infrared
FTS – Fourier Transform Spectrometer
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GWP – Global Warming Potential
GHG – Greenhouse Gas
GOSAT – Greenhouse Gas Observing Satellite
H2S – Hydrogen Sulfide
HyTES - Hyperspectral Thermal Emission Spectrometer
ICS - Incident Command System
JPL – NASA Jet Propulsion Laboratory, California Institute of Technology
LA County Fire/HazMat - Los Angeles County Fire Department/Hazardous Materials
Division
LADPH - Los Angeles County Department of Public Health
MCL – Maximum Contaminant Level
MSL – Mean Sea Level
NCP - National Oil and Hazardous Substances Pollution Contingency Plan
NASA – National Aeronautics and Space Administration
NOTAM – Notice to Airmen
NGSS Task Force - Federal Interagency Task Force on Natural Gas Storage Safety
NIST – National Institute of Standards and Technology
NOAA – National Oceanic and Atmospheric Administration
NRS - National Response System
NRT - National Response Team
OES – California Office of Emergency Services
OPA - Oil Pollution Act
OEHHA – California Office of Environmental Health Hazard Assessment
pCi/l – Picocuries per liter
PM2.5 – Particulate matter less than 2.5 micrometers in diameter
PAH – Polycyclic Aromatic Compound
PHES – Public Health and Environment Subgroup of the NGSS Task Force
REL – Reference Exposure Level
RRT - Regional Response Team
SVOC – Semivolatile organic compound
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SCAQMD - South Coast Air Quality Management District
SoCalGas - Southern California Gas Company
SLAMS – State and Local Air Monitoring Station
SS-25 - Well site: Standard Sesnon-25
TCCON – Total Carbon Column Observing Network
UCLA FSPH - University of California, Los Angeles, Fielding School of Public Health
USGS - United States Geological Survey
VOC - Volatile organic compound